FR3019420A1 - BASE STATION FOR A RADIO ACCESS NETWORK EMITTING CHARGE INFORMATION - Google Patents

Abstract

The invention relates to a base station for a radio access network, comprising a radio access and at least one link connecting said base station to the heart of a communication network, characterized in that the base station (3) is configured to radiofrequency a load information taking into account the load of the link with the core network (34) associated with said base station (3). The invention also relates to a radio access network comprising such a base station and a method of connecting a user terminal (5) to a base station (2, 3) of the access network (1).

Description

BACKGROUND OF THE INVENTION The present invention relates to the field of radio access networks such as wireless telephony networks. BACKGROUND OF THE INVENTION More specifically, the invention relates to such a radio access network comprising at least a first base station and a second base station, and to a method of connecting a user terminal to a base station of the access network. radio.

With reference to FIG. 1, a radio access network 1 comprises at least a first base station 2 and a second base station 3. Each of the base stations 2, 3 comprises a radio access 31, 21. These radio accesses 21, 31 allow a user terminal 5, for example a mobile phone, to communicate with the base stations to access a communication network.

At least the second base station is connected by a link 34 with the core network. It is an intermediate link between the second base station 3 and the heart of a communication network, said core network may be designated by the term "core network". This link 34 with the core network is generally wired, for example an optical fiber or an asymmetric digital link (ADSL for the English Asymmetric Digital Subscriber Line), but it can also implement wireless technologies, such as microphones. -ondes. Link 34 with the core network is commonly referred to as "backhaul". When a user terminal 5 is attached to a base station, the user terminal exchanges data by radio frequency with this base station. This data travels to the heart of the communication network via the backhaul link with the core network.

As illustrated by FIG. 1, it usually happens that the position of a user terminal 5 makes it able to communicate with both of the base stations 2, 3, since the user terminal 5 is able to capture the radio frequency messages transmitted by each of the base stations 2, 3. This situation frequently occurs in the case of a heterogeneous network, in which a first macro base station has a large first coverage area 22 of communication radiofrequency, while one (or more) second base station, said pico or femto for example, covers a much smaller area 32 generally comprised entirely in the first coverage area 22. An arbitration must be made for the attachment of the terminal user 5 to either of the base stations 2, 3. Typically, the network operator's policy involves imposing the attachment choice in order to balance the loadings. between the base stations 2, 3.

The latest generation of wireless access network systems for mobile telephony such as LTE-Advanced version 11 (Long Term Evolution Advanced for long-term advanced evolution) defined by the 3GPP consortium (3rd Generation Partnership Project, for 3rd generation cooperation project), provide a load balancing mechanism between the base stations for the attachment of the user terminal 5. The method used to select the base station to which the user terminal is connected generally rests on a metric comparison associated with each of the base stations 2,3. The metric mi associated with a base station i takes into account the sum of the power of a pilot radiofrequency signal Pi originating from said base station i received by the user terminal and a distribution parameter transmitted by said base station. base i, designated by CIO for the English "Cell Individual Offset": Mi = Pi + C101 For example, the power is expressed in dBm, but can be expressed differently, while the CIO is a homogeneous resetting variable to a power for example in dB.

The user terminal 5 compares the metrics associated with each of the base stations 2,3, and is connected to the base station 2,3 offering the best metric: i = arg max [Pk + CIOk} k The distribution parameter CIO, since it is summed with the power of the signal received from a base station, it amounts to shifting this power (hence the term "offset"). Thus, the coverage area of the second station 3 varies according to the distribution parameter CIO of this second base station 3. Reducing the distribution parameter CIO amounts to moving from a coverage area 32 for the second station to a higher one. small coverage area 33, and vice versa. The distribution parameter is generally determined to balance the loads of the radio accesses of the base stations, such a load can for example be defined as being the utilization rate of the scheduler of the base station, or even the number of users of the base station. The distribution parameter CIO is then determined so that a base station whose radio access is lightly loaded sees its CIO increase, therefore its coverage area, therefore all the user terminals it serves. The article entitled "Self-organization in wireless networks: a flow-level perspective", by Richard Combes, Zwi Altman and Eitan Altman, in INFOCOM, 2012, IEEE Proceedings, pages 2946-2950, presents an example of such a configuration. . In this example, for the second station 3, the distribution parameter CI02 is determined iteratively by the latter by an update based on a difference between the radio access load pl associated with the first base station 2 and a load p2 radio access associated with the second base station 3: CI02 (t + 1) = IC02 (t) E x (p1 (t) - p2 (t)) where E is a predetermined positive constant governing the speed of the balancing the loads between the base stations 2, 3. If the load of the second base station 3 is lower than that of the first base station 2, the IC02 of the second station will increase. User terminals 5 of a larger coverage area 32 will therefore connect to the second station 3 instead of connecting to the first base station 2. There is therefore an increase in radio traffic related to the second station of base 3 and a decrease in the radio traffic linked to the first base station 2. This refers to load shedding of the first station 2 ("off-loading" in English). However, the data rate capabilities of the radio access of a base station and its link with the core network may differ significantly. In addition, these capabilities are not necessarily used at the same time, so that the link 34 with the core network of a base station 2, 3 can be saturated, while its radio access is not. In addition, the link 34 with the core network may not be entirely dedicated to the traffic coming from the radio access of the base station, and its capacity to be reduced by traffic linked to other sources. For example, a data stream intended for a television set may use part of the capacity of the link 34 with the core network; this is for example commonly the case in a femtocell. The authors of the present invention have realized that in such a configuration, the distribution parameter CIO of the second base station 3 may increase in accordance with the mechanism described above since only the load of the radio access is taken in fact, even though the user terminals 5 connected to this second base station 3 can not obtain a satisfactory level of service because of the saturation of the link 34 with the core network. Therefore, in the case where the load of the link 34 with the core network of the second base station 3 is already too high, this increase in the CIO results in an increase in the number of the user terminals connected to the second base station. 3, and a collapse of the quality of service for them, for example via a drop in the data rate obtained by the user terminals 5. PRESENTATION OF THE INVENTION One of the aims of the invention is to overcome disadvantages of state-of-the-art systems such as those mentioned above. In particular, there is provided a base station for a radio access network, comprising a radio access and at least one link connecting said base station to the heart of a communication network, characterized in that the base station is configured to radiofrequency sending a load information taking into account the load of the link with the core network associated with said base station.

There is also provided a radio access network comprising at least a first base station and a second base station, each of said base stations comprising a radio access and at least the second base station being connected by a link with the core of a communication network, characterized in that at least the second base station is configured to radiofrequency sending a load information taking into account the load of the link with the core network associated with said second base station. The transmission by a base station of load information taking into account the load of the link with the core network associated with said base station allows the user terminals to connect by taking into account the load of the link with the core network associated with said base station, and thus to balance the loads between the base stations, improving the quality of the service offered to the user terminals. The access network is advantageously completed by the following characteristics, taken alone or in any of their technically possible combinations: the load of the connection with the core network is representative of the proportion used of the capacity of the connection with the core a network allocated to the rate of traffic passing through the radio access network of the second base station; the load of the connection with the core network is representative of the ratio between the total flow of the radio access traffic of the second base station transiting through the link with the core network and the sum of the available capacity of the link with the core network and said total rate; the load information taking into account the load of the link with the core network is a function of a global load corresponding to the average of the proportion of time in the presence of elastic traffic and the proportion of time in the absence of elastic traffic, said proportion of time in the absence of elastic traffic being weighted by the load of the link with the core network in the absence of elastic traffic, said load in the absence of elastic traffic corresponding to the maximum between - the proportion of the radio access capacity of the second base station used during a given period of time, and - the link load with the core network corresponding to the ratio of the total bit rate of the radio access of the second base station transiting the link with the core network and the sum of the available capacity of the link with the core network and said total bit rate. This formulation of the load makes it possible to take into account the elastic aspect or not of the traffic, and its real repercussion on the occupation of the resources of the base station, much better than a simple accounting of the terminals users connected to the access radio.

In the case where the link with the core network of the second base station is dedicated to the traffic of the radio access network of the second base station, the load information taking into account the load of the link with the heart network is a function of a global load corresponding at most between the load of the radio access of the second base station and the load of the link with the core network, said load of the link with the core network corresponding to the ratio between the total rate of the radio access traffic of the second base station transiting through the link with the core network and the capacity of the link with the core network of the second base station. In one embodiment, the load information taking into account the load of the link with the core network is a distribution parameter determined iteratively by the second base station by an update based on a difference between an associated load. to the first base station and a load associated with the second base station and taking into account a load of the link with the core network of said second base station. There is also provided a method of connecting a user terminal to a base station of a radio access network, in which - at least the second base station transmits by radio frequency a load information item taking into account the load of the link with the core network associated with said second base station; the user terminal receives said load information taking into account the load of the link with the core network associated with said second base station; the user terminal determines a metric associated with each of the base stations, the metric associated with the second base station taking into account the load load information transmitted by said second base station, the user terminal compares said metrics associated with said base stations and connects to one or the other of said base stations based on this comparison. The connection of the user terminal thus takes into account the load of the link with the core network, without however requiring reconfiguration of the user terminal.

The load information taking into account the load of the link with the core network can be a distribution parameter and the metric associated with a base station takes into account the sum of the power of a pilot radio frequency signal coming from said base station received by the user terminal and said distribution parameter. This distribution parameter is determined iteratively by the base station by an update based on a difference between a load associated with the first base station and a load associated with the second base station and taking into account a load of the link. with the core network of said second station.

PRESENTATION OF THE FIGURES The invention will be better understood, thanks to the following description, which refers to embodiments and variants according to the present invention, given as non-limiting examples and explained with reference to the attached schematic drawings. , among which: - Figure 1, described above, schematically shows a radio access network, and - Figure 2 schematically shows steps of a connection of a user terminal to a base station of a network. radio access according to a possible embodiment of the invention.

DETAILED DESCRIPTION As previously described and as illustrated in FIG. 1, a radio access network 1 comprises at least a first base station 2 and a second base station 3, each of said base stations 2, 3 comprising an access radio and at least the second base station 3 is connected by a link 34 with the core network in the heart of a communication network. Typically, each of the base stations 2, 3 is connected by a link with the core network 24, 34 which is associated with it at the heart of a communication network. Typically, the radio access network 1 consists of a larger number of base stations, some of which are divided into so-called "macro" stations of high power, therefore of wide coverage, and in stations of lower powers, called example "pico" or "femto", depending on the network nomenclature. In the following, we are interested in the relationship between two base stations 2, 3, and more precisely the load balancing between these two base stations. A base station notably comprises a processing unit equipped with a processor and a memory, in particular for processing the communication signals that are sent and sent. Of these, at least the second base station 3 is configured to radiofrequency a load information taking into account the load of the link 34 with the core network associated with said second base station 3. The first station of base 2 can also radiofrequency transmit a load information taking into account the load of the link with the core 24 associated with it. In a possible embodiment, the load information may be in the form of the aforementioned distribution parameter CIO, except that this parameter now takes into account the load of the link 34 with the core network in addition to the loads. radio access. The load of the link 34 with the heart of the network that is taken into account is representative of the proportion used of the capacity of the link 34 with the core network allocated to the rate of the traffic passing through the radio access network 31 of the network. second base station 3. More precisely, the load information taking into account the load of the link 34 with the core network is a function of a load of the link 34 with the core network pBH corresponding to the ratio between the bit rate total DRAR of the radio access traffic 31 of the second base station 3 transiting through the link 34 with the core network and the sum of the available CBridispo capacity of the link 34 with the core network and said total DAR rate: The total flow D of the radio access traffic is a known quantity of the scheduler ("scheduler" in English) of the second base station 3, which therefore makes it easy to obtain it. The CBridispo available capacity of the link 34 with the core network corresponds to the proportion of the CBH capacity of the link 34 with the core network left available by the utilization rate pBH of the link 34 with the core network, c i.e. the utilization rate of the link with the core network for both radio traffic and traffic via other elements having access to link 34 with the core network. The CBH capacity of the link 34 with the core network is intrinsic data builder of the link 34 with the core network and informed as soon as the establishment of the link 34 with the core network. The utilization rate pBH corresponds to the ratio between the total total DBH flow flowing in the link 34 with the core network and the CBH capacity of the link 34 with the core network: T DBH total PBH CBH The total flow DBH The total flowing in the link 34 with the core network can for example be determined downstream of the link with the core network and be sent back to the base station 3. It is also possible to determine the usage rate pBH. through a measurement of the available bit rate in the connection with the core network by means of a probe.

The load of the link 34 with the core network pBH can therefore be written in the following form: DRAR PBH = (1 - piti'H) CBH DRAR This load pBH of the link 34 with the core network is taken into account by the load information through an overall global load nr which is said load information function. This Poobai global load is intended to be representative of the actual load of the base station which will determine its ability to serve the users connected to it satisfactorily, in particular by taking into account the specificities of elastic traffic and inelastic data traffic. . "Best effort" traffic is defined as traffic for which delays and flows are adjustable and unsecured, whereas inelastic traffic is characterized by minimum flow and maximum delay requirements. . For example, real-time multimedia data exchange, such as a telephone conversation, is inelastic traffic.

Traditionally, the load is determined in a network as the average of resource utilization rates over a given time interval TkY k P 1Tk where yk is the proportion of radio resources used during the time interval Tk. However, this formulation of the load is not satisfactory because it does not take into account the elasticity or not of the traffic. For elastic traffic, it is assumed that all resources are used as long as there is a user to serve. Which gives a new formula of the load as the proportion of time when there are users to serve: Tkl {'k> 0} P = Ldrk where xk is the number of users to serve during the time interval Tk, and 1 {x> 0} is the indicator function on the set of positive x's (it is equal to 0 if x = 0, and equal to 1 if x is strictly positive). Assuming that in the presence of elastic traffic, all resources are occupied until the traffic is evacuated, the overall load can then be written as the average between the load in the presence of elastic traffic and the load in the absence of elastic traffic: Pglobal = Ek Tkltxek> 01 EkTkltxek = 0} MaX (yk, Ek Tk PBH, k) Where xe, k is the number of users generating elastic traffic during the time interval Tk, 1txe , k> 01 is the indicator function on the set of xe, k positive (it is equal to 0 if xe, k = 0, and equal to 1 if xe, k is strictly positive), and 1 {rek = 0} is the indicator function of the x, k is null (it is equal to 0 if xek (40, and equal to 1 if xe, k = 0).) In the scheduler of a base station, x, e, k can be obtained by reading the number of radio bearers in use of elastic traffic used, and the proportion yk of radio resources used during the time interval Tk can be calculated from r the proportion of resource blocks used.

Thus, the overall load Pglobal corresponds to the average of the proportion of time in the presence of elastic traffic and the proportion of time in the absence of elastic traffic, said proportion of time in the absence of elastic traffic being weighted by the load the link 34 with the core network in the absence of elastic traffic, said load in the absence of elastic traffic corresponding to the maximum between - the proportion yk of the capacity of the radio access 31 of the second base station 3 used during a given time interval, and - the load of the link with the core network pBH. This formulation of the load makes it possible to take account of the users who download a file, but which at times do not receive any data (the scheduler of the second base station 3 does not serve them) because the capacity of the link 34 with the core network is limited. Indeed, these users continue to contribute to the number of users to serve xe, k and therefore to increase the load. It also takes into account that when there is only regular-rate, ie inelastic, traffic, the overall load of the second base station is the maximum between the load of the radio access (ie yk) and the load pBH of the link 34 with the core network. It should be noted that in the case where the link 34 with the core network of the second base station 3 is dedicated to the traffic of the radio access network of the second base station 3, the load pBH of the link 34 with the heart of the network taken into account corresponds to the utilization rate pBH of the link 34 with the core network: PBH = PBH PBH = LBH In this case, the overall load Pglobal simply becomes the maximum between an access network load PRAR and the load pBH of the link of the second base station 3 with the core network Pglobal = max (PRAR; Pm) with the load of the access network pRAR corresponding to the occupancy rate of the scheduler of the second base station 3: Ek Tk 1tx ,, k> 01 + EkTki {x, k = 0} Yk PRAR EkTk where yk is the proportion of radio resources used during the time interval Tk, xe, k is the number of users generating elastic traffic during the time interval Tk, 1 {xe, k> 0} is the indicator function on the set of s xe, k positive (it is equal to 0 if xe, k = 0, and equal to 1 if xe, k is strictly positive), and 1 {re, k = 0} is the indicator function of the x, k null (it is equal to 0 if xej (40, and equal to 1 if xe, k = 0).

The load information taking into account the load of the link 34 with the core network may be the distribution parameter CIO, determined iteratively by the second base station 3 by an update based on a difference between a load associated with the network. the first base station 2 and a load associated with the second base station 3 and taking into account a load of the link 34 with the core network of said second base station 3, which is the overall load Pglobal CI02 (t + 1) = IC02 (t) EX (p1 (t) - rglobal (t)) where E is a predetermined positive constant governing the speed of load balancing between base stations 2, 3. As explained in the introductory part , this distribution parameter CIO is used for the connection of a mobile terminal 5 to one or other of the base stations 2, 3. It is therefore not necessary to modify the operation of the user terminals 5, since they were already using a te the distribution parameter. Taking account of the load of the link 34 with the core network of the second base station 3 does not change the processing by the user terminals 5 of the load information received in the form of the distribution parameter CIO. Thus, the method of connecting a user terminal 5 to a base station 2, 3 of the radio access network 1 is as follows. In accordance with the above, at least the second base station 3 radiofrequency a load information taking into account the load of the link 34 with the core network associated with said second base station 3. The user terminal 5 is typically a mobile phone. It is provided with at least one processor for processing the data and a radio module for communicating by radio frequency. The user terminal 5 receives said load information taking into account the load of the link 34 with the core network associated with said second base station 3, and the user terminal determines a metric associated with each of the base stations 2, 3, the metric associated with the second base station 3 taking into account the charge load information transmitted by said second base station 3. As explained above, the charging information is typically the distribution parameter CIO, and the associated metric to a base station takes into account the sum of the power of a pilot radiofrequency signal Pi from said base station i received by the user terminal and the distribution parameter CIO; transmitted by said base station. Insofar as the distribution parameter CI02 emitted by the second base station 3 takes into account the load of the link 34 with the core network of the said second base station 3, this load of the link 34 with the core network is also taken into account by the metric associated with the second base station 3. It can be the same with the first base station 2. Thus, with reference to FIG. 2, the first base station 2 transmits its pilot signal Pi and its distribution parameter CIO 1 (step S1) and the second base station 3 transmits its pilot signal P2 and its distribution parameter C102 (step S2). The user terminal 5 receives these (step S3). The user terminal 5 then determines (step S4) a metric associated with each of the base stations 2, 3. The user terminal 5 compares (step S5) said metrics associated with said base stations 2, 3 and connects, or is attached to, at one or other of said base stations 2, 3 based on this comparison (step S6). Typically, in configurations where the metric is a mere sum of the pilot signal power and the dispatch parameter, the user terminal 5 connects to the base station 2,3 having the best metric. If the overall load of the second base station 3 is less than the load of the first base station 2, the CIO issued by the second station 3 will increase. User terminals 5 of a larger coverage area 32 will therefore connect to the second station 3 instead of connecting to the first base station 2, which has the effect of offloading the first station. On the contrary, if the overall load of the second base station 3 is greater than the load of the first base station 2, the CIO transmitted by the second station 3 will decrease. The coverage area of the second base station 3 will therefore decrease to the extent that user terminals 5 previously in the extended coverage area 33 of the second base station 3 are now outside the restricted coverage area 32 of that base station 3. second base station 3, and will thus connect to the first station 2 instead of the second base station 3. Thus, since the distribution parameter CIO transmitted by the second base station 3 takes into account the load of the link With the core network, the method according to the invention makes it possible to balance the number of user terminals 5 between the first and the second base station according not only to the respective load of their radio access, but also according to the load connection with the core network of at least one of them, so as to avoid saturating this link. This advantageously results in an improvement of the quality of service offered to the user terminals 5, and a better distribution thereof between the base stations 2, 3. The invention is not limited to the embodiment described and represented in the appended figures. Modifications are possible, particularly from the point of view of the constitution of the various elements or by substitution of technical equivalents, without departing from the scope of protection of the invention.

Claims (10)

REVENDICATIONS1. Base station for a radio access network, comprising radio access and at least one link connecting said base station to the heart of a communication network, characterized in that the base station (3) is configured to transmit by radiofrequency a load information taking into account the load of the link with the core network (34) associated with said base station (3). 2. A radio access network (1) comprising at least a first base station (2) and a second base station (3), each of said base stations (2, 3) comprising a radio access and at least the second base station (3) being connected by a link with the core (34) of a communication network, characterized in that at least the second base station (3) is configured to radiofrequency a load information taking into account the load of the link with the core network (34) associated with said second base station (3). 3. radio access network according to the preceding claim, wherein the load of the link with the core network (34) is representative of the used proportion of the capacity of the link with the core network (34) allocated to the debit traffic passing through the radio access network (31) of the second base station (3). 4. Radio access network according to one of claims 2 to 3, wherein the load of the link with the core network (34) is representative of the ratio between the total bit rate of the radio access traffic (31) the second base station (3) passing through the link with the core network (34) and the sum of the available capacity of the link with the core network (34) and said total bit rate. 5. Radio access network according to one of claims 2 to 4, wherein the load information taking into account the load of the link with the core network (34) is a function of an overall load corresponding to the the proportion of time in the presence of elastic traffic and the proportion of time in the absence of elastic traffic, the said proportion of time in the absence of elastic traffic being weighted by the load of the link with the core network ( 34) in the absence of elastic traffic, said load in the absence of elastic traffic corresponding to the maximum between - the proportion of the capacity of the radio access (31) of the second base station (3) used during an interval given time, and - the load of the link with the core network corresponding to the ratio between the total bit rate of the radio access (31) of the second base station (3) transiting through the link with the core network ( 34) and the sum of the available capacity the link with the core network (34) and said total rate. 6. radio access network according to one of claims 2 to 5, wherein the connection with the core network (34) of the second base station (3) is dedicated to the traffic of the radio access network of the second base station, and the load information taking into account the load of the connection with the core network (34) is a function of an overall load corresponding to the maximum between the load of the radio access of the second station of base (3) and the link load with the core network (34), said link load with the core network corresponding to the ratio of the total traffic rate of the radio access (31) of the second station base (3) passing through the link with the core network (34) and the capacity of the link with the core network (34) of the second base station (3). 7. radio access network according to one of claims 2 to 6, wherein the load information taking into account the load of the link with the core network (34) is a distribution parameter determined iteratively by the second base station (3) by an update based on a difference between a load associated with the first base station (2) and a load associated with the second base station (3) and taking into account a load of the link with the core network (34) of said second base station (3). A method of connecting a user terminal (5) to a base station of a radio access network (1) according to any one of claims 2 to 7, wherein - at least the second base station (3) radiofrequency a load information taking into account the load of the link with the core network (34) associated with said second base station (3), - the user terminal (5) receives said load information taking in account the load of the connection with the core network (34) associated with the said second base station (3), the user terminal determines a metric associated with each of the base stations (2, 3), the metric associated with the second base station (3) taking into account the load charge information transmitted by said second base station (3), - the user terminal compares said metrics associated with said base stations (2, 3) and connects to one or other of said base stations (2, 3) s on the basis of this comparison. The method according to claim 8, wherein the load information taking into account the load of the connection with the core network (34) is a distribution parameter and the metric associated with a base station (2, 3). takes into account the sum of the power of a pilot radiofrequency signal from said base station (2, 3) received by the user terminal (5) and said distribution parameter. The method of claim 9, wherein the distribution parameter is determined iteratively by the base station (2, 3) by updating based on a difference between a load associated with the first base station (2) and a load associated with the second base station (3) and taking into account a load of the link with the core network (34) of said second station.