FR2905547A1 - CONNECTABLE NETWORK EQUIPMENT FOR WIRELESS NETWORK IN INFRASTRUCTURE MODE - Google Patents

Abstract

A network equipment comprising or forming an AP3 access point of a WLAN4 wireless network comprises means potentially capable of instantiating a STA10-NIU, IS1-NIU, IS2-NIU wireless network interface per client terminal STA10 station. , or intermediate IS1-NIU, IS2-NIU, wireless LAN WLAN4. It can thus have as many network interfaces as connected wireless stations. The inter-network bridge function 30 manages each of these wireless network interfaces instantiated according to the invention as any network interface.

Description

CONNECTABLE NETWORK EQUIPMENT FOR WIRELESS NETWORK IN INFRASTRUCTURE MODE

  The present invention relates to the field of WLAN (Wireless Local Area Network) wireless local area networks, and more particularly to the access point topology of such networks operating in infrastructure mode. State of the Prior Art Various WLAN wireless LAN technologies have been developed, including WI-FI technology based on the IEEE 802.11 standard. Other technologies exist, such as WiMAX (IEEE802.16). The infrastructure mode is a mode of operation that allows to connect together stations equipped with an ad-hoc network card, a WI-FI card for example, via an access point. The access point is thus an obligatory passage of communication. An example of state-of-the-art WLAN infrastructure wireless LAN is shown in Figure 1a. It comprises an API access point with a wireless network card 10 with a radio transmission / reception antenna in a coverage area 11 and client stations STA1, STA2, STA3, STA4 located in this coverage area. For example, STA1 is a laptop, STA2 is a camera, STA3 is a video monitor, and STA4 is a phone. In a business context, it could be basically computers and phones.

  In the following, the WLAN1 wireless local area network is confused with the set formed by the API access point and its STA client stations; 11 In the technical literature, this set is also called basic service set (BSS), or cell.

As detailed in FIG. 1b, the API access point comprises a corresponding WLAN-NIU wireless network interface port for the WLAN1 network. This interface typically comprises the wireless network card 10, with its transmitting / receiving antenna and a corresponding card driver or "driver", and a bridge function (Bridge) 12 implemented in a software manner to provide transmission. messages between STA client stations; of the WLAN1 network. In a known manner, bridge means a function that provides access control to the medium, corresponding to the data link layer of the medium. As an example of a Wi-Fi network, the well-known 802.11 standard defines the low layers of the Open Systems Interconnection (OSI) model, which is the Tier 1 physical layer, and the Tier 2 data link layer, broken down into two sub-layers, the logical link control sub-layer, and the Media Access Control (MAC) sub-layer. A bridge is a software or hardware function that manages data frames based on the source and destination MAC addresses indicated in the header of the frames it receives from a source station to the destination station.

The access point of a wireless network thus implements a bridge function that allows the client stations of the wireless network in question to communicate with each other through the wireless network interface port. This wireless network bridge mechanism is specific to the wireless network. Indeed, in a wired local network (for example an Ethernet local area network), two stations of the same wired local network communicate with each other directly. Initially, the client stations of a wireless LAN were intended to be terminal stations ("end-user station"). This means that these stations were not supposed to be connected to other network equipment by any means whatsoever. As the needs have evolved, new technologies have been developed, such as the Worldwide IEEE 802.16-based WIMAX (Worldwide Interoperability for Microwave Access) technology, which makes it possible to envisage other architectures, particularly in order to extend the coverage. network communication. We speak in particular of extended wireless network. These technologies make it possible to connect different networks to one another via access points. A Wimax access point thus includes, in addition to its wireless network interface, several other network interface ports or NlUs (for "Network Interface Unit"). It also implements an inter-network bridge function that allows data to be directed from one port to another, depending on MAC addresses. Referring to FIGS. 1a and 1b, the AP1 access point is thus a "WIMAX" connectable network device, which provides an inter-network bridge function, between at least the WLAN1 wireless network and another LAN1 local area network. . In the example illustrated, the local area network LAN1 is a wired network, for example an Ethernet network, to which an STA5 station is connected, for example a video server. In known manner, the AP1 access point comprises or implements for each network interface port, a corresponding driver, to manage the hardware interface suitably associated and a bridge function between inter-network or inter-NIU bridge between different NIUs network interface ports. In the example there is thus an inter-network bridge 20 for managing the MAC frames between the WLAN-NIU wireless network interface and the LAN1-NIU interface, through their respective drivers. This bridge 20 is implemented in a software way, by the operating system of the equipment AP1. In one example, if the operating system (Operating System) of AP1 access point is an open system such as for example the Linux or Windows system, ie which offers the possibility of implementing new functions, the bridge 20 is typically implemented by the kernel ("kernef") of the operating system, and for example implements the various functions included in the IEEE 802.1 standard, and in particular the so-called STP protocol for "Spanning Tree ProtocoP, by which a loopless network topology can be provided as defined in the IEEE 802.1D standard. The inter-NIU bridge 20 can not provide the bridge function 12 dedicated to the wireless network, because the management mechanism specific to the wireless network. Indeed, as soon as one inserts the wireless network card into the API equipment, the operating system opens or activates the corresponding WLAN-NIU wireless interface port. This interface port is common to all the client stations of the WLAN1 network thus activated. However, the inter-NIU bridge 20 makes it possible to direct messages arriving on a network interface, only to another distinct NIU interface. Indeed, this bridge function for managing the different network interfaces is based on a wired network communication protocol. According to this well-known protocol, all the stations of the same local network listen to the network. If one of them recognizes itself as being the recipient of a message on the network 15 (recognition of the recipient MAC address), it manifests itself. Also, if the message arrives on the access point, via the interface of this network is that no station of this network is recognized and the message is intended for a station of another network . Either the bridge knows by its routing table, which network belongs the destination station, and it transmits the message on the corresponding network interface, or it does not know, and it transmits the message on all other network interfaces. But in no case will he return the message on the interface from which he received the message. The inter-NIU bridge can not therefore direct messages received from the WLAN-NIU interface on this same WLAN-NIU interface.

For this reason and as illustrated in FIG. 1b, the API must implement the inter-network bridge 20 at the system level, and the bridge 12 inherent to the wireless network, at the wireless network interface WLANNIU. This "wireless" bridge 12 is dedicated exclusively to the WLAN-NIU wireless network interface and only relays data based on the MAC addresses between the client stations of the wireless network. Figure 2 illustrates the case of more complex network infrastructures in which end stations are connected to the wireless network by intermediate stations. To describe the infrastructure, we consider by pure convention, a descendant hierarchy starting from the access point. With this convention, in the example illustrated in FIG. 2, a WLAN2 wireless local area network comprises an access point AP2, and two intermediate stations IS1 and IS2. The intermediate station IS1 is an access point of another wireless network WLAN3 to which are attached two wireless stations STA6 and STA7. The intermediate station IS2 is connected to a LAN2 wired subnet, to which other STA8 and STA9 stations are also connected. These stations STA6 to STA9 are terminal stations, or end-user stations. The intermediate stations implement a bridge function, for example by the kernel of their operating system, to relay the frames according to their MAC address between terminal stations. In such an infrastructure, the bridge function 12 of the AP2 access point dedicated to the WLAN-NIU wireless network interface is more complex than in the previous case illustrated in FIG. 1a, since it must manage so-called hidden nodes, namely the terminal stations STA6 to STA9 which are located behind the intermediate stations IS1 and IS2, and which are not directly visible by the AP2 access point. Furthermore, in this case, the intermediate stations 20 acting as a link (node) between two local networks, in the example, between the WLAN2 wireless network and the LAN2 wired network, or wireless WLAN3, there is a risk well-known loops, which can paralyze the network, by phenomenon called "broadcast storm" (literally: broadcast storm). For this reason, the bridge function 12 of the wireless network interface of the access point AP2 must itself implement the STP protocol indicated above (IEEEI.D standard), implemented in the inter-network bridge 20. Technical problem The two examples of network infrastructure with access points of WIMAX type just given, show that the structure 30 with two bridges, an inter-network system bridge 20 and a dedicated wireless bridge 12, which are implemented in the AP2 access point (or in a network equipment including this access point) is not optimal and can even become complex in the case of a network hierarchy infrastructure, where the wireless network includes intermediate stations. In the invention, attempts have been made to simplify the design of these WAN infrastructures. A technical solution that is simple to implement, scalable and reliable has been sought for managing all the cases of direction of the messages within the access point, by the same bridge function, including in the case of sub-networks attached. to a wireless network, the idea being to remove the bridge function dedicated to the wireless network 10 implemented in the wireless network interface and / or the associated driver. SUMMARY OF THE INVENTION According to the invention, a network equipment comprising or forming an access point of a wireless network comprises means potentially capable of instantiating a wireless network interface per client, terminal or intermediate station, wireless LAN. There can thus be as many network interfaces as stations of the wireless network. The inter-network bridge function manages each of these wireless network interfaces instantiated according to the invention as any network interface. In particular, it is capable of directing frames sent by a station of the wireless network 20 to another station of this wireless network, because it sees them as two distinct network interfaces. By this method of instantiating a plurality of wireless network interfaces for the same wireless network, the contradictory mode of operation of the two bridge functions according to the state of the art is thus solved.

Advantageously, dynamic management of these network interfaces is implemented, as a function of the connections and / or disconnections of the stations of the wireless network. In addition, each instantiated wireless network interface includes a driver that may include features specific to the client station.

Particularly in the case of an intermediate station, the pilot may include features specific to this intermediate station.

The invention therefore relates to a network device connectable to at least two local networks, forming at least one access point to a wireless local area network, at least a first network interface port allowing a connection to a network. local, characterized in that said access point 5 comprises a plurality of wireless network interface ports associated with said wireless network, each of said wireless network interface ports being associated with at least one client station of said network without wire, and an inter-network bridge associated with at least said first network interface port and said plurality of wireless network interface ports.

In an advantageous variant, the access point is a router and makes it possible to associate with said wireless network, several IP subnetworks, one per client station. The invention also relates to a method of communication between local networks corresponding.

Other advantages and features of the invention are detailed in the following description with reference to the illustrated drawings of an embodiment of the invention, given by way of non-limiting example. In these drawings: FIGS. 1a and 1b already described illustrate a wireless network topology in infrastructure mode with an access point allowing connection to at least one other network according to the state of the art; FIG. 2 already described illustrates an extended wireless LAN topology with an access point according to the state of the art; FIG. 3 illustrates an extended wireless network topology with an access point according to the invention; FIG. 4 is a block diagram illustrating a dynamic instantiation method of a wireless network interface according to the invention; FIG. 5 is a diagram illustrating an application of the invention to a system in which the subnetworks are IP networks and the connectable equipment forming or comprising the access point is a router and FIG. 6 schematically illustrates an IP routing mechanism applicable to the invention.

DETAILED DESCRIPTION FIG. 3 illustrates an access point according to the invention in an extended wireless network topology. In this example, the wireless local area network WLAN4 comprises an AP3 access point, an STA10 terminal station, for example a portable computer, and two intermediate stations IS1 and IS2. For these intermediate stations, the example illustrated in FIG. 2 is repeated here, with the same notations. Thus, the intermediate station IS1 is an access point of a WLAN3 wireless subnet to which the STA6 and STA7 stations are attached. The intermediate station IS2 is connected to a wired subnet LAN2, to which are attached the stations STA8 and STA9. The access point AP3 has a LAN1-NIU network interface with a local area network LAN1, which in the example is wired, to which an STA5 station is connected. The AP3 access point also has a plurality of wireless network interface ports with the WLAN4 network. In the example, there are N = 3 wireless network interface ports, software instantiated, each associated with a terminal station, STA10 or intermediate, IS1, IS2, directly in view of the AP3 access point. By station is meant directly in view of the access point AP3, the stations of the wireless wireless network WLAN4, such as in the example STA10, IS1 and 182. The stations attached indirectly to the AP3 access point, via a Intermediate station, like STA6 STA9 stations in the example, are invisible to this access point, and therefore do not cause the instantiation of a corresponding wireless interface port in this access point.

In the example, three virtual interfaces can be instantiated: the STA10-NIU interface associated with the STA10 terminal station, the IS1-NIU interface associated with the intermediate station IS1, and the IS2-NIU interface associated with the intermediate station IS2. Each of these STA10-NIU, IS1-NIU, IS2-NIU virtual interfaces is treated by the inter-network bridge 30 as a separate network interface as soon as it is declared to it. Each of these network interfaces includes its driver and shares with the other interfaces, the wireless network card 10. The drivers Do, D ,, D2 of these interfaces STA10-NIU, IS1-NIU and IS2-NIU have a part Common A relating to the control of the wireless network card 10 that these interfaces all share in common. Each driver may furthermore comprise a specific part, respectively Bo, BI, B2, of the station of the WLAN4 network corresponding to the interface in question, or of STA1o, ISI, IS2, respectively. This specific part of the driver advantageously makes it possible to exploit particular functionalities of the station with which it is associated. This is advantageously the case for intermediate stations ISI and IS2 which are each attached to another local network. For example, the intermediate station IS1 could support a security mechanism of its own. The specific portion BI of the driver D1 of the associated interface will then include corresponding functionalities. These specific parts can be enriched with the need for new functionalities, depending on the evolution of the stations, especially the intermediate stations. There is thus an access point structure advantageously adaptable, modifiable, depending on the evolution of infrastructure. In the case where the access point is router, it is possible according to a feature of the invention explained below, to associate each virtual interface and therefore each station of the wireless network, an IP address. In this case, the associated driver, for example D1 comprises a specific part B1, at least to allow packet switching exclusively via said associated client station, and possibly to implement specific features of the associated station.

Potentially, there may be at any one time as many wireless network interface ports, and associated pilots as intermediate and terminal stations, directly for the access point wireless card 10. AP3. Advantageously, there are as many wireless network interface ports as there are stations directly in view, which are actually connected. This feature is advantageous because it allows one to manage at a given time, only the wireless network interfaces actually used, which frees up memory space and CPU power. This functionality is achieved simply by using the standard functionality of the access points combined with the wireless network cards, which are able to detect data transmitted by each of the wireless stations, indicating their active presence. In practice, when the wireless network card is activated (inserted, energized), there is an association phase, during which the stations connected to the access point are detected and corresponding information recorded as their MAC address. When a station 15 leaves the network, this is also detected. The instantiation means then uses this connection / disconnection information to dynamically manage the wireless network interface ports: delete the ports corresponding to disconnected stations, and / or instantiate new ones for stations that have 20 connected. The AP3 access point becomes comparable to a wireless dynamic switch (ie, it acts as a multi-port bridging switch), through which ports ( interfaces) are dynamically added or removed depending on the evolution of the network topology.In FIGURE 4, the mechanism for instantiating a wireless network interface port according to the invention is diagrammatically If the STAk station connects, this is detected (step 100.1a), and corresponding information is transmitted to the operating system instantiation means 100. 2 corresponding wireless network interface port 2905547 11 (step 100.3a): instantiation of the port and association of the STAk station to this port The inter-network bridge 30 must be updated (step 100.4). emitted to add this port in the int bridge For example, in an access point (or connectable network equipment implementing this access point) with a Linux operating system, using the notation "br0" to designate the inter-network bridge. 30, and assuming that two wireless network interface ports have already been instantiated, denoted wmax0 and wmaxl, and added in the bridge 30 (FIG. 4), the ADD command will be of the type: Brctl br0 addif wmax2.

The new wireless network interface port wmax 2 is then added in the bridge 30. If the STAk station disconnects, this is detected (step 100.1b), and corresponding information is sent to the instantiation means 100.2, which remove the interface port associated with it (step 103.b).

An LED command is issued to delete this port in the inter-network bridge 30 (step 100.4). The LED command will be of the type: Brctl br0 del / if wmax2. It will be noted that with an instantiation of virtual wireless network interface ports according to the invention, if no station of the wireless network 20 is actually connected to the wireless network, no interface port is created. . Thus, there may be at a given time for the WLAN4 wireless network, 0 instantiated wireless network interface port, or n instantiated wireless network interface ports, n nonzero integer. In practice, the number of wireless network interface ports that can be instantiated at a given time can be limited, essentially depending on the data processing and memory capabilities of the access point. In this case, in step 100.2, the access point can check the current number n of instantiated ports, and if the limit is reached, deny the request. In this case the STAk station is denied its connection to the WLAN4 wireless network.

The invention advantageously offers the possibility of IP (Internet Protocol) routing within the same wireless local area network in the case where the access point AP3 is a router, that is to say able to ensure IP routing of data between the different stations attached to this wireless network. This particularly interesting aspect of the invention makes it possible to associate an IP subnet with each instantiated wireless interface port associated with a station 5 of the WLAN4 wireless network. It is thus possible to share this WLAN4 wireless network, into several IP subnetworks. In particular, one can have an IP subnet by intermediate station of the wireless network. This aspect of the invention is more particularly described below with reference to FIG.

The AP4 access point comprises a router bridge 30R: in addition to the inter-network bridge functions, it implements IP packet switching functions 200 between the different interface ports instantiated in the access point. In order to carry out a corresponding IP routing, an IP address 15 is attached to each of the intermediate or terminal stations of the WLAN4 network at access point AP4. It is recalled that an IP address is formed of a network identification part or IP subnetwork, and a MAC machine identification part.

The AP4 router access point associates an IP subnet identifier with each instantiated port, and in particular with each new wireless interface port instantiated for the WLAN4 network. For those wireless interface ports instantiated for the WLAN4 network, the machine identification is the MAC-WLAN4 machine identification of the wireless network card 10 which manages the WLAN4 network. Each packet entering the access point AP4, the router bridge 30R analyzes the destination IP address in each packet that enters, and according to the network or subnet identification part, transmits the packet to the corresponding interface port.

Thus, in the example illustrated in FIG. 5, we have the following situation. At the intermediate station 181 and the terminal stations ST6 and ST7 attached thereto corresponds to an IP subnet, IP-0. At the intermediate station IS2 as well as at the terminal stations ST8 5 and ST9 which are attached to it corresponds an IP sub-network, IP-1. Each station associated with the considered IP subnet IP-0 or IP-1 has a corresponding IP address in that network. For example, the STA6 station has the IP-00 address. The LAN1 is associated with an associated IP subnet, IP-2 and the STA6 station at the IP-20 address in this IP2 subnet. At station STA19 corresponds an IP address, IP-3. An example of IP routing schematically illustrates in FIG. 6 a management of the IP layer by the inter-network router bridge 30R. In a step 200.a implemented by the routing functions 200, the inter-network router bridge 30R detects the destination IP address, for example the IP-10 address, in each data packet transiting through the data point. AP4 access, for example in a data packet entering through the ISI-NIU wireless network interface port. In a next step 200.b, it searches, for example in an IP TAB routing table that it keeps at 20 days, to which IP subnet and consequently which network interface corresponds to this IP address, to send it on this interface (step 200c). In the example, he finds that the IP-10 address belongs to the IP-1 subnet, and passes the data packet to the corresponding network interface port, in the IS2-NIU example.

In this context, it will be noted that each of the virtual interfaces instantiated for the wireless network WLAN4, and attached to a station of this network, for example IS1-NIU then comprises in its driver D1, in addition to the part A common to all the ports instantiated for the wireless network WLAN4, a specific part B1 of said station, at least to allow the switching of the IP packets from or to that station. Reference will be made to what has already been explained above about the drivers of the virtual interfaces. The invention applies to all network topologies comprising one or more wireless networks in infrastructure mode, without being limited to particular network standards. It makes it possible to envisage topologies of extended networks, to which it brings flexibility and adaptability. It is particularly applicable to WIMAX technology. 10

Claims (13)

  1. Network equipment connectable to at least two local networks, forming at least one access point (AP3) to a wireless local area network (WLAN4), at least one first network interface port (LAN1-NIU) allowing a connection to a local area network (LAN1), characterized in that said access point comprises a plurality of wireless network interface ports (STA10-NIU, IS1-NIU, IS2-NIU) associated with said wireless network ( WLAN4), each of said wireless network interface ports being associated with at least one client station of said wireless network, and an inter-network bridge (30) associated with at least said first network interface port and said plurality of ports wireless network interface.   Network equipment according to claim 1, characterized in that at each wireless network interface port (IS1) is associated at most one client station of the wireless network (IS1).   The network equipment according to claim 2, wherein said inter-network bridge (30R) implements IP routing functions (200), characterized in that said wireless network (WLAN4) comprises a plurality of IP subnetworks (IP). -0, IP-1, IP-3), an IP subnet being associated with each client station of the wireless network and the corresponding wireless network interface port.   4. Network equipment according to one of the preceding claims, characterized in that it comprises instanciation software means (100.2) for instantiating each wireless network interface port associated with said wireless network.   Network equipment according to claim 4, characterized in that said instantiation means are dynamic means for opening or closing wireless network interface ports as a function of connection information (100.1a) of client stations to said wireless network and / or disconnections (100.1b) of the client stations of said wireless network.   The network equipment according to any one of claims 1 to 5, wherein each wireless network interface port (STA10-NIU, IS1-NIU, IS2-NIU) instantiated for an associated client station comprises a own driver ( DO, D1, D2), said driver comprising at least a portion (A) specific to the wireless network card (10) of said access point (AP3).   7. Network equipment according to claim 6, characterized in that said driver further comprises a specific part (BO, B1, B2) corresponding to eigenfunctions of said associated client station.   8. Network equipment according to claim 6 in combination with claim 3, characterized in that said driver further comprises a specific part (BO, B1, B2) corresponding to IP routing functionalities for said associated client station.   Network equipment according to any one of the preceding claims, wherein said wireless network (WLAN4) is a WIMAX network. 20   A method of communicating in an access point (AP3) by means of an inter-network bridge (30) between at least two local networks, at least one of which is a wireless local area network (WLAN4), via associated network interface ports, characterized in that it comprises a step (100.3a) for instantiating and associating with each client station (IS1, IS2) of said said wireless local area network, a wireless network interface port (ISI-NIU, IS2-NIU), and a step of updating (100.4) the network interface ports available in said inter-network bridge (30).   11. The communication method as claimed in claim 10, characterized in that said instantiating step (100.3a) is triggered by detection (100.1a) of a connection of a client station of the wireless network. 2905547 17   12. Communication method according to claim 10, characterized in that it comprises a step of deleting (100.3b) a wireless network interface port, triggered by detecting a disconnection (100.1b) of the station associate client 5.   The communication method according to any one of claims 10 to 12, in a router type access point (AP4), wherein said inter-network bridge (30R) comprises IP routing functions (200), characterized in that in said step (1003.a) of instantiation of a wireless network interface port (IS1-NIU, IS2-NIU), a wireless network interface port is associated with a single client station, and in that said method comprises a step (200) associating with each of said wireless network interface ports instantiated for said wireless network (WLAN4), an IP subnet, said IP subnet being associated with the corresponding client station.