NL1028440C2 - Telecommunication system. - Google Patents

Description

Telecommunication system

The invention relates to a telecommunication system.

The telecommunications sector has expanded enormously in recent decades. Twenty years ago, the 5 most telecommunication providers drove on corded telephony. Today, wireless communication is the most important pillar. The demands that consumers place on telecommunication applications keep pace with the fast-growing technological possibilities. Quality, speed and costs are 10 important components of the package of requirements.

In response to these demands and the growing competition in the telecommunications market, developments in wireless telecommunication have accelerated. Third generation universal mobile telecommunications services (UMTS) networks, also known as wideband code division multiplex access (WCDMA) networks, are now being rolled out. The frequencies for these networks have been auctioned off in various countries, which has cost the telecommunications providers billions of euros. UMTS networks are supposed to give a new impulse to telecommunication development by enabling new wireless applications, such as wireless transmission and reception of large files, including e.g. video data, between mobile clients.

An alternative to such third generation tele-communication systems is described in US 2004/0103275. The publication describes a telecommunications network comprising portable nodes that are communicatively connected to establish wireless peer-to-peer communication between the nodes to form a wireless backbone of the network.

Each node has two wireless interfaces, one for backbone communication and one for providing a coverage area for wireless communication with mobile clients within this area. Every node can be provided with

J Λ Λ A i λ A

2 external antennas to extend the communication area of the wireless network interface.

A drawback of the telecommunication system according to the prior art is the limited coverage area of the no-5s for wireless communication with mobile clients.

As a result, there are limitations to the placement of the nodes and the distance between the nodes. Furthermore, as a result of the peer-to-peer communication between the nodes, the backbone quickly becomes saturated.

It is an object of the invention to provide an improved telecommunication system.

This object is achieved by providing a telecommunication system comprising a number of communication devices adapted to establish point-to-point connections with each other in order to form a wireless backbone of the telecommunication system, wherein at least one of the communication devices is also connected to at least one distribution communication station, which distribution communication station is in communication connection with at least a number of wi-reless access points which are arranged to provide access to the telecommunication system for wireless client devices. The distribution communication station preferably comprises one or more multipoint-to-point transmitter / receiver in-25 directions.

By providing the backbone with distribution communication stations that facilitate communication between the backbone and a second network of wireless access points, a larger coverage area is obtained. This resolves the problem which is referred to in telecommunications as "the last mile", ie the problem of providing network access in the last kilometer to the homes of users of mobile clients, without having to install UMTS antennas in the area placed. UMTS antennas typically have a lower bandwidth than the wireless access points according to the invention. The second network of wireless access points can be set up in such a way that communication in, for example, urban areas, including objects that are obstacles to wireless access! 1 02 RA A0_____ 3 communication forms is possible. The point-to-point nature of the backbone connections provides for a greater capacity of the backbone.

In a preferred embodiment according to the invention, the telecommunication system comprises a relay communication station for transmitting signals between the distribution communication station and one or more of the wireless access points. This preferred embodiment has the advantage that the network of wireless access points, depending on the range of the relay communication station, can be provided further from the backbone, whereby the range of the telecommunication system can be further extended.

In a preferred embodiment of the invention, the telecommunication system is adapted to communicate over the wireless backbone via a radio signal with a carrier frequency of 5.7-5.8 GHz and communication with the wireless access points takes place via a radio signal with a carrier wave. frequency of 2.4-2.5 GHz. These frequency bands are free frequencies, that is, not restricted by governments or licensed, that are suitable for high-quality and fast connections with a large bandwidth and coverage area. When a relay communication station is used, communication between the distribution communication station and the relay communication station preferably also takes place in the 5.8 GHz band for an optimum range and bandwidth.

In a preferred embodiment of the invention, the backbone comprises three communication devices positioned at the vertices of an imaginary triangle.

The triangle is preferably a substantially equilateral triangle. The triangle shape of the backbone optimizes the coverage area of the telecommunication system. Optionally, fourth and subsequent communication devices of the backbone can be installed on the sides of the triangle. In a particularly advantageous embodiment of the invention, a further communication device is positioned within the imaginary triangle and this communication device is arranged to establish point-to-point connections with one or _i (\? Ri i Q_ _ _ 4 more of the three communication devices of the backbone.

This further communication device provides redundancy for the telecommunication system in case, for example, a communication device of the backbone does not function or does not function optimally or because a certain connection temporarily does not function or does not function optimally. The loss of connections occurs, for example, in dynamic environments such as urban areas, because there are objects in the "line of sight" of the communication devices of the backbone (temporarily or otherwise) that disrupt communication. In all these cases, the further communication device, which is substantially centrally located in the imaginary triangle, provides an alternative connection on the backbone. To this end, the telecommunication system preferably comprises a routing decision system that, for example, runs a spanning tree protocol. The spanning tree protocol is standardized in the 802.ld IEEE spec and can be run in a switch of the telecommunications system to determine which of the different connections is the best communication channel. Furthermore, the telecommunication system is preferably arranged such that the load on the backbone can be regulated automatically and adaptively. Such a routing decision system and / or load control system preferably runs on a central, e.g., triangle-located, communication device and the backbone communication devices in a master-slave hierarchy.

In a preferred embodiment of the invention, the telecommunication system comprises a further communication device which is adapted to send and receive data from outside the telecommunication system. This embodiment makes it possible to communicate with devices outside the coverage area of the telecommunication system. The further communication device, which is preferably situated substantially centrally in the backbone, thus feeds the telecommunication system with data and can, for example, provide access to, for example, IP networks, ATM networks, etc. The further communication unit thus provides the possibility of communication outside the coverage area of the telecommunication system. In a special embodiment, the telecommunication network is adapted to communicate with other networks via a satellite. This satellite connection can for instance take place via the further communication device. This makes it possible to use the telecommunication system in, for example, remote areas.

The invention will be explained below with reference to the accompanying Figures, which show embodiments according to the invention. It will be clear that the invention is by no means limited to these preferred embodiments.

In the Figures:

FIG. 1 a telecommunication system according to a preferred embodiment of the invention; FIGs. 2A and 2B show wireless backbone configurations;

FIG. 3 a further communication device of the telecommunication system of FIG. 1;

FIG. 4 a communication device of the telecommunication system of FIG. 1

FIG. 5 a communication device connected to a distribution transmitter of the telecommunication system of FIG. 1;

FIG. 6 a distribution transmitter connected to a relay station of the telecommunication system of FIG. 1; FIGs. 7 and 8 a relay station in communicative connection with a number of wireless access points of the telecommunication system of FIG. 1;

FIGs. 9 and 10 show examples of local in long-distance communication using the telecommunication system and

FIGs. 11-14 show an example of a non-public IP addressing scheme for use in the telecommunication system as shown in FIG. 1.

FIG. 1 shows a telecommunication system 1 according to a preferred embodiment of the invention, which system 1 is adapted for mobile communication. The telecommunication system 1 comprises a number of communication devices 2, hereinafter also referred to as transmitters 2, which are adapted to maintain point-to-point OQA Ad 6 point connections 3, 4, 5 in order to provide a wireless backbone of the telecommunication system 1 to shape. A backbone is a connection or set of connections that can transport large amounts of data that are offered to or provided by the communication devices 2, which in this context are also referred to as nodes or telecommunication data switching exchanges (DSEs). The communication devices 2 are positioned at the vertices of an imaginary equilateral triangle.

The telecommunication system 1 also comprises a further communication device 6 which also maintains point-to-point connections with one or more of the communication devices 2 and is also connected to a satellite 7 for communication outside the telecommunication system 1.

According to an embodiment of the invention, at least one of the communication devices 2 is in communication connection with a distribution transmitter 8. The distribution transmitter 8 is, for example, a multipoint transmitter, such as the heavy-duty multipoint Tsunami MP.11. of Proxim, which is in communication connection with a relay station 9 and also maintains connections with stations 10. Although in FIG. 1, only one distribution channel is shown for only one of the communication devices 2, in practice many or all communication devices 2 will be connected to one or more distribution transmitters 8. The relay station 9 is in communication connection with a number of wireless access points 20 that are arranged to provide access to the telecommunication system 1 to wireless client devices 21, such as laptops, personal digital assistants, telephones, etc. in a wireless LAN environment. An example of such wireless access points are the ORiNO-CO access points from Proxim. The wireless access points 20 can be configured such that they can communicate with each other to send data to the backbone via intermediate access points 20. It is noted that the wireless access points 20 also communicate directly with the communication device 2 in may be connected when, for example, the af | position from the communication device 2 to the wireless access j 1 028440 __ _ 7 points 20 can be bridged immediately. As shown, wireless access points 20 can each also be connected to the relay station 9 (see also Figs. 7 and 8).

In a preferred embodiment of the invention, the specifications of the telecommunication system 1 are as follows. For the wireless communication, the telecommunication system 1 preferably uses the free frequencies according to the 802.11 IEEE standard, also referred to as the wireless fidelity (WiFi) standard. The point-to-point transmitters of the communication devices 2 radiate in the free 5 GHz band, such as the 5.7-5.8 GHz WiFi-A band, and the connections can have a data transport speed between 20 Mbit / s and 480 Mbit / s. The distances between the point-to-point transmitters, in this case the sides of the triangle backbone, are in the area 10-120 km. The connection between a multipoint transmitters 8 and a relay station 9 or station 10 also preferably operates in the 5.7-5.8 GHz WiFi-A band and the distance to be bridged is preferably between 2 and 25 kilometers. Per 20 multipoint transmitter 8, for example, a maximum of 1024 connections can be entered with a data transport speed between 20 Mbit / s and 108 Mbit / s.

From the relay station 9 to and from the wireless access points 20 and then to the mobile client 21, the data transmission then preferably takes place in the also free 2.4-2.5 GHz WiFi b or g band of the point to-point WiFi a-band. The capacity of such wireless access points 20 is, for example, between 300 mW and 1W. The selected band is dependent on the PCI or PCMIA card of the mobile client. 21. Communication takes place using the TCP / IP

protocol, preferably supported by a security protocol. The WiFi card of the mobile client 21 has a unique MAC (media access control) address and a capacity between 10-300 mW.

35 For the TCP / IP connection between the mobile clients 21 and the wireless access points 20, the wireless access points 20 issue temporary IP addresses by applying DHCP (dynamic host communication protocol). The telecommunication system 1 is preferably arranged such that one or more wire-less access points 20 can use the same IP addresses. Distinction between the connections can be made using the MAC address of the wireless access 5 point 20. The IP addresses issued by the wireless access points 20 can be non-public IP addresses, such as IP addresses in the 10.O.x.x range.

In the Figs. 2A-8 different aspects of the telecommunication system 1 are explained in more detail.

FIGs. 2A and 2B show two different configurations for the backbone of communication devices 2. Although the triangular configuration offers certain advantages, such as optimum coverage of the telecommunication system 1 and redundancy in the connection possibilities with the communication devices 2, this configuration is not necessary for the invention. Other configurations of point-to-point connections for the backbone, such as a square (Fig. 2B), a pentagon and a hexagon (not shown) are possible. Further communication units 2 can also be positioned on the sides of the configurations.

FIG. 3 shows the central communication device 6 in further detail. The central communication device 6 comprises a mast 30 provided with antennas 31, 32, 33 for setting up point-to-point connections with the respective communication devices 2. The antennas are communicatively connected to a switch 34, at preferably a Net Layer 2 switch, which in turn is connected to a server or server park 35 and a monitoring system 36.

The server 35 is connected to a further antenna 37 for communication with the satellite 7 outside the telecommunication network 1. It is noted that the server can alternatively or additionally also maintain one or more other connections so that communication outside the telecommunication system 1 is possible, e.g. with or via an IP, FTP and / or an ATM network.

In this way, the central communication device feeds the telecommunication system 1 with data and offers the possibility of communicating with devices outside the telecommunication system 1, i.e., long-distance. The server 35 1028440 also provides a DNS (domain name system) server and a parallel proxy for quickly making data available to users of the telecommunication system 1. The central communication device 6 also provides e.g. on the server 5 ver 35 a firewall and NAT bridging (network address translation) in internet protocol version 6 (ΙΡνβ) of the IEFT standardization organization. NAT bridging is used for converting IP addresses used within the telecommunication system 1 to known IP addresses outside the telecommunication system 1. This aspect will be further explained below. Communication under IPv6 provides the possibility to realize fully virtual connections instead of stacking sockets as is currently happening with internet protocol version 4. This opens up the possibility of setting up a much larger number of connections, which benefits the performance of the telecommunication system 1.

The monitoring system 36 provides for AAA functionality (Accounting, Authorization, Authentication), also referred to as RADIUS, and receives status information 20 of the various components of the telecommunication system 1 via SNMP (simple network management protocol). The monitoring system 36 monitors and monitors the data flows on the backbone. The monitoring system 36 can also contribute to the load optimization of the telecommunication system 1.

FIG. 4 shows one of the communication devices 2 in further detail. The communication device consists of a mast 40 provided with antennas 41, 42, 43 for establishing the point-to-point connections 3,4; 4,5 or 3,5 with other communication devices 2 and with the central communication device 6 via an antennae 31; 32; 33. The antennas 41,42,43 are connected via a switch 44, preferably a Net Layer 2 switch, to, for example, a Voice over IP (VOIP) gateway 45 which in turn is connected to a telephone exchange 46. As a result, telephone traffic can be transmitted over TCP. / IP 35 over the wireless backbone. The switch 44 has a load optimization functionality and a stress tree routing decision system.

1028440 10

The switch 4 is also connected to a server or server park 50, as shown in FIG. 5. Incidentally, the switch 44 may also be connected to other backbone applications, digital television (e.g. video on demand). The server 50 comprises a DNS server and a parallel proxy that are configured as slaves with respect to the master DNS server and master parallel proxy of the central communication device 6. The communication device 2 can also have IPv6 firewall and NAT -bridging functionality on the server 50 is 10.

The server 50 is communicatively connected to distribution transmitters 8 via again a switch 51. The distribution transmitters or multipoint transmitters 8 can be arranged such that they can together cover a 360 ° coverage area around the central communication device 2. It will be clear that the coverage area can be adapted to the specific circumstances.

FIG. 6 shows one of the multipoint transmitters in communicative connection with a number of further stations 10. These connections can be used as heavy duty connections, also called business-to-business (B2B) connections, for large-scale commercial use. One or more of the stations 10 can also be used as a relay station 9 for communication with the wireless access points 20. For communication with the wireless access points 20, the relay station 9 comprises a multiway access point 60 provided with a base descriptor unit (BDU). Such an access point with BDU can use a connection at full bandwidth as a multipoint-to-point connection. This makes it possible to create a mi-30 ni backbone whereby maximum bandwidths are maintained without, like in a peer-to-peer arrangement, saturating the bandwidth.

The "last mile" of the telecommunication system 1 is accomplished by providing wireless access 35 points 20 as shown in Figs. 7 and 8 (or through a direct connection to the stations 10). A distribution transmitter 8 and / or relay station 9 is communicatively connected in the 2.4 - 2.5 GHz wifi b, g or a band with the wireless access points 20.

1028440 11

In a street S1, for example, each wireless access point 20 can be individually directly connected to the relay station 9, so that a wifi star network is formed. A wifi distibution bridge (spanning tree) can also be applied, wherein the wireless access points 20 communicate with each other, as represented for a state S2.

One of the factors that determines the configuration of wireless access points 20 is the environment, such as the presence of obstacles such as high buildings HB. FIG. 8 shows a practical example in which the network of wireless access points 20 is brought into the streets S.

It is noted that the wireless access points 20 can also be arranged inside a building, so that communication via the telecommunication system 1 can also take place indoors.

FIG. 9 gives an example of local use of the telecommunication system 1. For simplification, the relay communication stations 9 and the central communication device 6 are not shown. A user A in possession of a mobile client 21 wants to communicate with a user B, also in possession of a mobile client 21. To that end, the mobile client of user A searches for a connection in the 2.4-2.5 GHz band with a wireless access point 20 that is within its reach. The communication path then proceeds via the distribution channel 8, the switch 51, the server 50, the switch 44 and the antenna 43 of the communication device 2 over the point-to-point backbone (5.7-5.8 GHz ) from the telecommunication system 1 to the communication device 2 at B. Here the communication path is traversed in the reverse direction.

FIG. 10 (not to scale) gives an example of long-distance use of the telecommunication system 1. The arrows indicate a communication path from the mobile client 21 from A to the mobile client from B. It will be clear that the connection is also active in the reverse direction . Again 35, the mobile client 21 seeks connection to an accessible wireless access point 20. The relevant wireless access point 20 is in communication connection (2.4-2.5 GHz) with the multiway access point 60 (see Fig. 7) of the relay station 9 1028440 12 (star configuration of Fig. 7 is used). From the relay station 9, the 5.7-5.8 GHz band is communicated with the distribution transmitter 8 to the server 50. Via the switch 44 a point-to-point connection 5 is then found over the antenna 41 to the antenna 31 from the central communication device 6. Via the switch 34 and the server 35, the data is then sent via antenna 37 of the central communication device 6 to a long-distance connection station, such as the satellite 7. From the satellite 7, the communication path is traversed in reverse order to the mobile client 21 of B.

When a mobile client 21 moves and comes outside the range of a wireless access point 20, a subsequent wireless access point 20 must take over the connection. This mechanism is commonly referred to as roaming in telecommunications. Roaming takes place via the switch 51 when within the range of the multipoint transmitters 8 and over the backbone when roaming is required between different communication devices. Roaming via the switches of the telecommunication system 1 has the advantage that no routing tables need to be kept.

FIGs. 11-15 finally show an example of an IP address scheme for the further communication device 6 (FIG.

11), the communication devices 2 and the distribution transmitters 8 (Figs. 12A-12C). The abbreviation NIC stands for network interface card. The abbreviations Ext. and Int. stand for external resp. internal. The abbreviation Gw stands for Gateway.

The telecommunication system 1 consists of several Net Layer 2 switches 34, 44, 51 and servers 35, 50 and 30 operating in the bridging mode. The switches 34, 44, 51 divide the telecommunication system into various segments. Net Layer 2 switches send data packets on the link layer (this is the second layer in the so-called OSI model) based on the MAC address of the packet between the segments. Such switches 35 require no change on the IP layer (the third OSI layer).

The switches 34, 44, 51 used are preferably transparent, which means that the switches have a learning functionality to remember once established communication paths and to set up quickly with repeated use. The switches also provide the option to make the telecommunication system redundant using the spanning tree protocol.

The backbone of the telecommunication system 1 acts as a large transparent switch for communication about this system in that each of the communication devices 2 and the further communication device 6 comprise such Net Layer 2 switches. This is shown in FIG. 13.

The use of MAC addresses of the various components in the telecommunication system 1 is limited by applying the IPv6 servers 35, 50 to the communication devices 2 and the further communication device 6. These IPv6 servers function as NAT bridges in IPv4, which translates the incoming IP addresses into a single IP address whereby the connections between the communication devices 2 and with the further communication unit 6 remain 'clean'. Dynamic MAC tables are built in these servers for converting from MAC to MAC. The transmission of 20 data in the IP layer 3 is converted to the bridge layer (layer 2), while the data flow on the TCP / IP layer is handled as a standard package. Transparency is achieved because the MAC address of the sender is included in the TCP / IP package. In this way it is possible to re-use it on non-public IP addresses, such as the series 192.168.X.X for the backbone (see Fig. 14).

The 10.0.x.x series is used by the distribution transmitters 8, as shown in Figs. 12A-12C. Each distribution channel 8 can set up 1024 connections, which means a total of approximately 4000 connections for four of such distribution channels. If 16 channels are assumed, this means that approximately 64000 connections can be handled using the non-public 10.0.x.x IP address scheme.

35 1028440

Claims (10)

A telecommunication system (1) comprising a number of communication devices (2) which are arranged to establish point-to-point connections with each other in order to form a wireless backbone of the telecommunication system 5, wherein at least one of the communication devices is also connected to at least one distribution communication station (8), which distribution communication station is in communication connection with at least a number of wireless access points (2) arranged to provide access to the telecommunication system for wireless client devices (21). 2. The telecommunication system (1) according to claim 1, wherein a relay communication station (9) is provided for transmitting signals between the distribution communication station (8) and one or more of the wireless access points (20). 3. The telecommunication system (1) according to claim 1 or 2, wherein the telecommunication system is adapted to communicate over the wireless backbone via a radio signal with a carrier wave frequency of 5 ^ 7-5.8 GHz and communication with the wireless access points (20) take place via a radio signal with a carrier wave frequency of 2.4-2.5 GHz. The telecommunication system (1) according to one or more of the preceding claims, wherein the backbone comprises three communication devices (2) positioned at the corner points of an imaginary triangle. The telecommunications system (1) according to claim 4, further comprising a further communication device (6) which is positioned within the imaginary triangle and is arranged to establish point-to-point connections with at least one or more of the three communication devices (2) of the backbone. The telecommunication system (1) according to one or more of the preceding claims, wherein the telecommunication system 1028440 is arranged to regulate the load on the backbone and / or comprises a routing decision system. 7. The telecommunication system (1) according to one or more of the preceding claims, wherein the telecommunication system comprises a further communication device (6) which is adapted to send and receive data from outside the telecommunication system. 8. The telecommunication system (1) according to claim 6, wherein the telecommunication system is adapted to communicate with a satellite (7). The telecommunication system (1) according to one or more of the preceding claims, wherein two or more wire-less access points (2) are communicatively connected. The telecommunication system according to one or more of the preceding claims, wherein at least one of the communication devices comprises a network layer 2 bridge (34, 44, 51) and a NAT device (35, 50). 1028440