Prevention of congestion at radio access in a mobile or wireless communication system

Description

CROSS-REFERENCE TO RELATED APPLICATIONS

This application is based on European Patent Application No. 09305957.4 filed Oct. 8, 2009, the disclosure of which is hereby incorporated by reference thereto in its entirety, and the priority of which is hereby claimed under 35 U.S.C. §119.

FIELD OF THE INVENTION

The present invention generally relates to mobile or wireless communication networks and systems.

BACKGROUND

Generally, descriptions of mobile or wireless networks and systems can be found in the literature such as in particular in Technical Specifications published by standardisation bodies. Examples of standardisation bodies include 3GPP (3^rdGeneration Partnership Project), IEEE (Institute of Electrical and Electronics Engineers) . . . etc.

In the following, mobile networks and systems such as specified by standardization bodies such as for example 3GPP will mainly be considered, as an example to which embodiments of the present invention applies. However embodiments of the present invention are not limited to such example.

An example of a mobile communication system is recalled in FIG. 1. The mobile network may be a PLMN (Public Land Mobile Network) such as those supporting GSM, UMTS, LTE, CDMA, Wimax, etc. . . . technologies for public telecommunication but may also encompass satellites based networks.

As illustrated in FIG. 1, a Mobile Terminal MT has access via a Radio Access Network RAN to communication services provided by a Core Network CN. Examples of Radio Access Network (RAN) include GERAN (for 2G GSM/GPRS), UTRAN (for 3G UMTS), E-UTRAN (for 3G LTE), . . . etc. The RAN generally has a cellular architecture, therefore the RAN includes a plurality of network entities such as Base Stations (such as BS1, BS2, BS3). Examples of Base Stations include 2G BTS (Base Transceiver Station), 3G Node B. 3G LTE ENB (Evolved Node B), . . . etc.

SUMMARY

Historically mobile networks were mainly designed for enabling voice communication between human beings. Then some additional services were added, e.g. data service, SMS, . . . .

Currently, a new kind of communications is emerging: the Machine-to-Machine communication (M2M). In M2M, the communication is not between human beings but between two machines that doesn't need necessarily human interaction.

With the development of Machine to Machine (M2M) communications (e.g. captors, sensors, . . . ) huge amounts of new automatic M2M Mobile Terminals are going to be deployed.

As recognized by the inventors of the present application, as those M2M Mobile Terminals are not directly controlled by human beings, there is the risk that some automatic algorithm in the various M2M Mobile Terminals induce that they ask simultaneously for communication network resources. If (too) many of those terminals are deployed in the same radio cell, there is the risk that they simultaneously request radio resources inducing a congestion or overflow of radio resources and of radio base station resources. Actually the highest risk is that of an overflow of radio signaling capabilities and of Base Station signaling capability (CPU) as each of those M2M Mobile Terminals may not request a high radio throughput.

Currently this issue is not solved. Currently the M2M market is emerging. The number of M2M devices that are managed via a mobile network is currently not huge, but it is foreseen that in the next future some applications (e.g. Smart Metering) could have to manage several millions of new M2M devices.

Even before this massive deployment, this issue may arise at cell level. It locally a high number of M2M mobile devices is installed, the problem could appear in one cell.

Embodiments of the present invention in particular enables to solve such problems and/or avoid such drawbacks. More generally, it is an object of embodiments of the present invention to improve radio access, and finally quality of service, in a mobile or wireless communication system, particularly (though not exclusively) for M2M communication.

These and other objects are achieved, in one aspect, by a method for preventing congestion at radio access in a mobile or wireless communication system.

Said method comprises, in an embodiment, a step of:

- barring a Mobile Terminal from radio access, except if said Mobile Terminal belongs to a given one of different ranges into which Mobile Terminals are split, said given range being referred to as allowed range, said allowed range changing upon time.

These and other objects are achieved in other aspects, by entities such as in particular Mobile Terminal (such as in particular M2M Mobile Terminal), and network entity (such as in particular Base Station), for carrying out such method.

BRIEF DESCRIPTION OF THE DRAWINGS

Some embodiments of apparatus and/or methods in accordance with embodiments of the present invention are now described, by way of example only, and with reference to the accompanying drawings, in which:

FIG. 1 is intended to illustrate an example of a mobile communication system,

FIG. 2 is intended to illustrate a high level view of a M2M mobile communication system,

FIG. 3 is intended to illustrate prevention of congestion according to an embodiment of the present invention.

DESCRIPTION OF EMBODIMENTS

From a high level point of view, a M2M system can generally be represented as illustrated in FIG. 2.

The Back Office systems contains the Applications that manage the M2M Devices and the data handled by them.

The M2M Information System is in charge to manage the communications with the M2M Devices via a specific Communication Network.

The Communication Network allows to transport data from/to Applications to/from M2M Devices or M2M Gateways. This network can be a public network (e.g. 3GPP, TISPAN, CDMA, . . . ) or any other kind of network (Ethernet, PLC, . . . ).

A M2M Gateway is a specific M2M network element that is in charge to manage some M2M Devices via a M2M capillary network. A lot of types of capillary network (wired or wireless) are currently existing depending on the kind of handled data, the kind of topology, topography, range, . . . . One of the main goals of a M2M Gateway is for example the aggregation of the data collected from the M2M Devices before sending them in a more concentrated way to the central Application.

A Back Office system can exchange messages with M2M Devices by using some specific protocols.

Some M2M Systems can handle a huge number of M2M Devices (for example in Smart Metering in which the M2M Application remotely collect the value of each M2M Device that are the electricity counters).

In the following a M2M Mobile Terminal may be

- A M2M device accessing directly to the mobile network
- A M2M Gateway that is in charge to manage some M2M Devices via a M2M capillary network and to support access to a mobile network on behalf of these M2M devices.

In order to solve the above-mentioned problems and/or avoid the above-mentioned drawbacks, an application level throttling mechanism could be foreseen where the application/M2M information system takes care that all the M2M devices it handles do not try to contact the application at the same time.

However, as further recognized by the inventors of the present application:

- As there may be many simultaneous M2M applications, an application level throttling is likely not to be able to control the load in a given cell. (especially since some M2M Devices can move so it brings an additional level of complexity for an application level throttling)
- Furthermore M2M devices may need to communicate with other entities that the M2M application (e.g. to communicate with a NW server for synchronization purposes). The (radio) network accesses of M2M devices may thus be independent from the M2M application and thus should be controlled at a lower layer.

In an embodiment of the present invention, it is proposed to:

- split the M2M Mobile Terminals into sub-sets of terminals (M2M ranges of terminals) and to
- bar any radio access from M2M Mobile Terminals except if they belong to a given M2M range and to
- rotate (cycle) upon time the value of the range (of M2M terminals) that is allowed to have radio access on a given cell.

In other words, a radio access throttling is done at radio level (cell level) and is independent of the M2M application. It is independent from and has a different objective as any M2M related application level throttling that may be enforced at individual M2M application level between the M2M Information System and the M2M mobile terminals. The M2M application level throttling protects an individual application and is independent of where (cell) the M2M mobile terminal is camping.

Note that the wider the cell is (satellite cells, cells using a low frequency radio), the higher the need for a mechanism as proposed.

In the following a more detailed description of an embodiment of the present invention will be provided.

In an embodiment, the Radio Access Network (RAN) broadcasts in its beacon the following M2M related information

- 1. Whether M2M Mobile Terminals are allowed/throttled/globally barred in the cell
- 2. When M2M Mobile Terminals are throttled in the cell, the value of the M2M range currently allowed in the cell.

In an embodiment, when the M2M Mobile Terminals want to access to the Radio Access Network they may (as illustrated in FIG. 3):

- 1. check that the cell they are camping on is not globally barred for M2M service
- 2. If the cell is globally barred for M2M service (as illustrated at 1), look for another cell or wait for the M2M service to be no more globally barred in the current cell (as illustrated at 2)
- 3. If the cell is throttled for M2M service (as illustrated at 3), check whether they belong to the M2M range that is currently allowed in the cell (as illustrated at 4)
- 4. If they do not belong to the M2M range that is currently allowed (for example a M2M Mobile Terminal belonging to range Y whereas X is the currently allowed range as illustrated in FIG. 3), then wait for this range to be allowed (regularly scan the related cell beacon information), as illustrated at 5, or possibly look for another cell.
- 5. If the cell is globally allowed for M2M service, or if the M2M Mobile Terminal belongs to the M2M range that is currently allowed (as illustrated at 6 and 7), for example a M2M Mobile Terminal belonging to range Y and range Y being the currently allowed range as illustrated in FIG. 3, then request an access to the cell (as illustrated at 8).

In this example, the throttling mechanism is combined with a mechanism of global allowance/barring; however these are independent mechanisms, the throttling mechanism could be considered independently of the global allowance/barring mechanism and vice versa, another aspect of embodiments of the present invention being the global allowance/barring mechanism for M2M service in itself.

Various embodiments for implementing the throttling mechanism may be used, for example:

- 1. For a 3GPP M2M Mobile Terminal, the M2M range of the M2M Mobile Terminal may be determined based on a modulo operation on the last digits of the MSIN part of the IMSI of the M2M Mobile Terminal.
  - IMSI means International Mobile Subscriber Identity. It is defined in 3GPP 23.003, composed by the 3 parts i.e. MCC+MNC+MSIN with:
    - MCC=Mobile Country Code on 3 digits
    - MNC=Mobile Network Code on 2 or 3 digits
    - MSIN=Mobile Subscriber Identification Number on 10 digits.
  - The last digits of the IMSI, or MSIN digits, are evenly distributed among terminals.

In other words, in this example, a M2M Mobile Terminal may calculate the range R to which it belongs by performing a modulo operation, i.e. calculating the range R to which it belongs as the remainder after division of a number formed by last digits of the MSIN part of the IMSI, by a number associated with the modulo operation (or number of ranges).

- 2. For other M2M Mobile Terminals (such as for example IEEE M2M Mobile Terminals), the M2M range of a M2M Mobile Terminal may be determined based on a modulo operation (with the same principle as previously in 1) on the last (lower order) 24 bits of the MAC (Media Access Control) address of the terminal.
  - The lower order bits of the MAC address are being used as these bits are evenly distributed among terminals
- 3. The value of the M2M range currently allowed in the cell may be broadcast together with a number associated with a modulo operation (or number of ranges) in turn associated with this M2M throttling mechanism (as described above). This allows the operator e.g. to control the number of ranges into which M2M Mobile Terminals are split, for example to control whether it splits the M2M Mobile Terminals into 8, 16, 32, . . . ranges. M2M related parameters such as the value of the M2M range currently allowed and/or a number enabling a M2M Mobile Terminal to calculate its range may be broadcast as system information on a broadcast channel such as for example Broadcast Control Channel BCCH.
- 4. The Throttling may apply only to the M2M Mobile Terminal initiated accesses, i.e. it may not apply when the M2M Mobile Terminal is being paged.
- 5. The application protocol may define “urgent” application messages that overcome this mechanism and that may be sent only in very specific (urgency) cases.

In one aspect, there is provided a method for preventing congestion at radio access in a mobile or wireless communication system.