FI105976B - Mobile station's high speed access to a TCP / IP network - Google Patents

Abstract

A mobile communication system comprises a mobile station (MS) and an interworking function (IWF) for establishing a high-speed point-to-point data connection to a data network access point (2), which supports a multilink point-to-point protocol PPP. The point-to-point connection comprises a first subleg between the mobile station (MS) and the interworking function (IWF) and a second multilink PPP subleg between the interworking function (IWF) and the access point (2). The first subleg between the mobile station (MS) and the interworking function (IWF) is allocated to as many subchannels or sub-traffic streams as there are channels (e.g. time slots of 64 kbit/s) on the second subleg between the IWF and the access point of another telecommunications network, such as an IAP server. Each channel of the fixed network connection as well as the PPP link payload carried by the channel are adapted to the allocated mobile network subchannel or substream so that the PPP payload is transmitted as such over the whole point-to-point connection between the multilink PPP protocol functions located in the mobile station and IAP server. This allows to avoid placing of PPP and multilink PPP protocols in the interworking function IWF.

Description

105976

High speed connection of the mobile station to the TCP / IP network

The invention relates generally to mobile communication networks and, in particular, to high-speed mobile access to a data network such as the Internet and the Intranet.

5 Mobile communication systems generally refer to various types of communication systems that enable personal wireless data transmission when subscribers move within the system. A typical mobile communication system is a ground-based public land mobile network (PLMN).

10 In addition to traditional voice communication, digital mobile systems offer many other services: short messages, fax, data transmission, etc. Of these, the data transmission service in particular gives the mobile subscriber access to almost all fixed network data services, but wirelessly.

In the fixed network, there has been an explosion of TCP / IP (Trans-15 Mission Control Protocol / Internet Protocol) data networks. Using the Internet. As is well known, the Internet is in fact made up of a large number of TCP / IP networks interconnected. Private TCP / IP networks, such as in-house, are also called Intranets.

Internet applications are used to connect to services on the Internet 20 network. Before you can connect to the Internet, you must have an agreement with an Internet Service Provider (ISP) that provides Internet access through one or more Internet Access Points (IAPs). An ISP can be, for example, a commercial operator (such as Eunet in Europe), a university or your own company. An IAP is typically a server that can be accessed by a user from a regular landline or mobile phone by making a modem (or data call) call to a specific IAP access number. Typically, servers provide modem access at speeds generally up to 56 kbit / s or ISDN access at 64 kbit / s.

Today, some Internet / lntranet servers offer 2B (2 * 64 30 Kbit / s) or even higher n * 64 kbit / s bit rates for ISDN subscribers. In other words: an ISDN subscriber is provided with a higher bit rate and bandwidth by bundling two or more 64 kbit / s physical ISDN channels into one logical link. The coordination of this bundle of physical channels is based on its multilink PPP protocol, which is defined by IETF RFC 1990 (Re-35 quest For Comments number 1990). Multilink PPP is a method for performing data division, sequencing, and recombining of 2,105,976 multiple channels. The primary objective of the method was to allow multiple parallel channels to be used on ISDN, but it is equally applicable to any situation where two systems are linked by multiple PPP (Point-to-Point Protocol) links. The point-to-point protocol (PPP) is a data encapsulation format defined by RFC 1661 and 1662, recommended for encapsulation protocol, as well as for bit-oriented synchronous links and asynchronous links.

FIG. 1 illustrates a multilink PPP connection between an ISDN terminal (TE) 1 and an IAP server 2 over an ISDN network 3. A plurality of (n> 2) ISDN channels ch1-chn are connected between the TE and the server 2. Each channel has 10 PPP links formed between its respective PPP protocol blocks 4n and 5n, i.e. n independent PPP links. These independent PPP links are coordinated by the multilink protocol blocks 6 and 7 to provide a virtual connection with a bandwidth greater than any of its partial links (PPP links). Blocks 6 and 7 divide the Datagrams 15 received from the TCP / IP units 8 and 9 into PPP channels at the transmission end and compile the data frames received from the PPP channels at the reception end and forward them to the TCP / IP units 8 and 9. The connection has no flow control.

High-speed data services in existing mobile networks, such as the High Speed Circuit Switched Data (GSM) system (HSCSD 20), offer bit rates up to 64 kbit / s. multichannel technology and new channel coding technologies. In multichannel technology, the mobile station is provided with a higher bit rate and bandwidth in the form of multiple parallel traffic channels (e.g., multiple time slots). In addition, ETSI (European Telecommunications Standards Institute) is in the process of developing data rates of more than 64 kbit / s for the GSM system. a new modulation scheme which provides a higher data rate per slot than the current GMSK modulation but retains a 200 kHz channel spacing and TDMA frame structure. This makes it possible to support existing data services with a smaller number of 30 time slots. In addition, it enables the production of new data services having: up to 64 kbit / s data rate per time slot or over 64 kbit / s in multi-time slot constellation.

Via data transmission services of mobile communication systems, the Internet / Internet network is also available to mobile subscribers, either directly from the mobile 35 network (the ΙΑΡ server is connected directly to the MSC network adapter IWF of the mobile switching center, e.g., through a dedicated 2 Mbit / s circuit) or via ISDN 3 105976 ( There is an ISDN between MSC / IWF and ΙΑΡ-server). Figure 2 illustrates Internet access over an ISDN network using a single link (data rate up to 64 kbit / s). The upper layers of the protocol are TCP / IP and PPP in the mobile station MS and the IAP server 2. Below these are the GSM traffic channel 5 between the MS-IWF and the ISDN channel between the IWF and the IAP server 2. The GSM traffic channel is configured as a non-transparent traffic channel using the L2R / RLP radio link protocol and the rate adaptations RA. The RLP is a wed-hysrakenteinen, balanced (HDLC-type) data transmission protocol in which error correction is based on retransmission of distorted frames at the request of left and 10 to the receiving party. Because of RLP, the ITU-T V.120 transport protocol with flow control mechanism must also be used on the ISDN channel.

When the above-mentioned data rates of more than 64 kbit / s are imported into mobile networks, support for the multilink PPP protocol must also be implemented in the mobile communication network in order to provide mobile subscribers with high-speed (n * 64 kbit / s) access to Internet / Internet networks.

One object of the invention is to provide high speed access to data networks such as TCP / IP networks that support the multilink PPP protocol.

This is achieved by the mobile communication system of claim 1, the mobile communication device of claim 12, the network adapter of claim 16, and the method of claim 20.

In accordance with the basic principles of the invention, a partial connection between a mobile station and an IWF is divided into as many subchannels · * 25 or sub-traffic as the second connection portion between the IWF and another communication network access point such as an IAP server has channels (e.g. 64 kbit / s). Each fixed network connection channel, as well as the payload of the PPP link it carries, is matched to a subchannel or downstream of the mobile network allocated thereto, such that the PPP payload is transmitted over the entire end-to-end connection between the multicast and IAP servers. This avoids placing PPP and multilink PPP protocols in the IWF network adapter.

There are several ways to divide a subset of a cellular network into subchannels or sub-streams. Owing to the susceptibility of the radio connection to interference between the mobile station 35 and the Network Adapter, a proprietary link access control protocol LAC is used, which has a retransmission error correction.

4, 105976

In some mobile communication systems, this protocol is called a radio link protocol RLP.

In one embodiment of the invention, there is a separate LAC link and a physically separate traffic channel or traffic stream between the mobile station and the Network Adapter for each PPP link (and PPP subchannel).

In another embodiment of the invention, there is a separate LAC protocol link between the mobile station and the Network Adapter for each PPP link and one common broadband traffic channel for each PPP link. The mobile station and the Network Adapter multiplex the PPP links to this broadband traffic channel. For example, multiplexing may be performed by multiplexing the frames of each separate LAC protocol link into said broadband traffic channel. In yet another embodiment of the invention, there is one common LAC protocol link between the mobile station and the Network Adapter for all PPP links, and the PPP subchannels are multiplexed within the LAC protocol link.

Preferred embodiments of the invention will now be described with reference to the accompanying drawings, in which Figure 1 illustrates a multilink PPP connection on an ISDN network, Figure 2 illustrates a single link PPP connection to an Internet / Intranet network, Figure 3 illustrates a GSM mobile communication system, recommended protocols and functions in non-transparent network services, Figure 5 illustrates a protocol structure for a non-transparent HSCSD connection according to GSM, · Figure 6 illustrates a multilink PPP-supporting connection between a mobile station MS and an IAP server, Figure 7, 8 and 9 illustrate multilink PPP connections according to various embodiments of the invention, and Figures 10 and 11 illustrate multiplexing PPP links into RLP-30 frames.

The present invention is applicable to all digital wireless communication systems, such as cellular systems, WLL (Wireless Local Loop) and RLL (Radio Local Loop) networks, satellite-based mobile communication systems, etc. As used herein, mobile system (or network) generally refers to all wireless systems. communication and information systems. There are a number of multiple access modulation techniques to facilitate • - * 5 105976 traffic involving a large number of mobile users. These techniques include time division multiple access (TDMA), code division multiple access (CDMA), and frequency division multiple access (FDMA). The physical concept of the traffic channel varies in different multi-access methods, being primarily defined by time slot in TDMA systems, spreading code in CDMA systems, radio channel in FDMA systems, a combination of these, etc. In modern mobile systems, a set of so-called. high-speed traffic channel. Here, the term li-10 traffic channel refers to both a single basic rate traffic channel and a high speed traffic channel formed by two or more basic rate traffic channels. The basic idea of the present invention is independent of the type of traffic channel and the multiple access method used.

The present invention is particularly suitable for data communication applications in the pan-European Global System for Mobile Communications (GSM) and other GSM-based systems such as DCS1800 (Digital Communication System), US Personal Communication System (PCS), and GPRS 20 ( General Packet Radio Service) and WLL systems based on the above systems. The invention will be described below using the GSM mobile communication system as an example. The structure and operation of the GSM system are well known to those skilled in the art and are defined in the GSM specifications of the European Telecommunications Standards Institute (ETSI). Reference is also made to book 25, "GSM-System for Mobile Communication", by M. Mouly and M. Pautet, Palaiseau, France, 1992; ISBN: 2-9507190-0-7.

The basic structure of the GSM system is shown in Figure 3. The GSM structure consists of two parts: the base station system BSS and the network subsystem (NSS). The BSS and the mobile stations MS communicate via radio links 30. In the base station system BSS, each cell is served by the base station BTS. A plurality of base stations are connected to a base station controller BSC whose function is to control the radio frequencies and channels used by the BTS. The BSCs are connected to the mobile services switching center MSC. Certain MSCs are connected to other telecommunication networks, such as the public switched telephone network PSTN, and include gateway functions for outgoing and incoming calls to these networks. These MSCs are known as gateways (GMSC). In addition, there are at least two databases, the home location register HLR and the visitor location register VLR.

Services of mobile communication systems can generally be divided into telecommunication services and bearer services. The network service is a telecommunication service that provides the transmission of signals between user-network interfaces. For example, modem services are network services. In telecommunications, the network also provides terminal services. Important telecommunication services, on the other hand, are voice, fax and videotex services. Network services are usually divided into groups based on some feature, such as asynchronous network services and synchronous network services. In an asynchronous network service, the transmitting and receiving terminals maintain their synchronization only for each individual character that is transmitted. In a synchronous network service, the sending and receiving data terminals are synchronized with each other throughout the data transmission. Within each such group is a set of online services, such as a 15 transparent service and a non-transparent service. In Transparent, the data to be transferred in the service is unstructured and the transmission errors are corrected only by channel coding. In the non-transparent service, the data to be transmitted is structured into Protocol Download Units (PDUs) and transmission errors are corrected (in addition to channel coding) by automatic retransmission protocols.

The mobile communication system has adapter functions for adapting the internal data connection of the mobile network to the protocols used by terminals and other telecommunication networks. Typically, the adapter functions are in a terminal adapter TAF (Terminal Adaptation Function) interface between a mobile station and a data terminal connected thereto, and an IWF (Interworking 25 Function) network adapter interface between a mobile network and another communication network, usually in connection with a mobile switching center. Usually, the mobile switching center has several types of adapter hardware pools to support various data services and protocols, e.g. Between the TAF 31 and the Network Adapter IWF 41 in the mobile network. In non-transparent data services, the GSM connection also uses the radio link protocol RLP. The TAF adapts the data terminal DTE connected to the mobile station MS to said GSM data connection, which is established over a physical ψ 7 105976 connection using one or more traffic channels. The IWF connects the GSM data connection to another network, such as GSM, ISDN or PSTN, or directly to, for example, an IAP server.

Figure 4 illustrates the protocols and functions required in IWF (either MSC or WLLL-specific network element) for non-transparent network services. The non-transparent circuit switched connection between the terminal adapter TAF and the network adapter IWF over a GSM traffic channel comprises a plurality of protocol layers common to all of these services. These include various rate adaptation functions RA, such as between the TAF of the RA1 'terminal adapter and the CCU unit 10 in the base station system BSS, between the RA1 CCU and the Network Adapter IWF, between the RAA CCU and the transcoder stationed separately from the base station. , and between the TRAU transceiver unit RA2 and the IWF Network Adapter. The speed adaptation functions RA are defined in GSM Recommendations 04.21 and 08.20. The communication between the CCU and the transcoder unit TRAU is defined in GSM Recommendation 08.60. In addition, the RAT rate matched information at the radio interface is channel coded as defined in GSM Recommendation 5.03, illustrated by the blocks FEC in the mobile station MS and the CCU. In addition, IWF and TAF have higher level protocols that are service specific. In an asynchronous non-transparent network service 20, the IWF requires L2R (Layer 2 Relay) and RLP (Radio Link Protocol) protocols, as well as a modem or speed adapter to the fixed network. L2R functionality for non-transparent character-oriented protocols is defined e.g. GSM Recommendation 07.02. The RLP protocol is defined in GSM Recommendation 04.22. RLP is a frame-structured, balanced (HDLC-type) · '25 data transmission protocol in which error correction is based on the request of the receiving retransmission of distorted frames party. The interface between the IWF and, for example, the MODEM audio modem is in accordance with CCITT V.24 and is indicated in FIG. 5 by the symbol L2. This non-transparent configuration is also used to access the Internet.

In the HSCSD concept of the GSM system, the high-speed data signal is divided into separate data streams, which are then transmitted over N subchannels (N traffic channel slots) at the radio interface. Once the data streams are divided, they are transported in the subchannels as if they were independent, until they are combined again in IWF or MS. However, logically, these N sub-35 carrier channels belong to the same HSCSD connection, i.e., form one HSCSD traffic channel. According to GSM recommendations, data stream sharing and

•. X

Combining 105976 is performed in a modified RLP, which is thus common to all subchannels. Below this common RLP, each subchannel separately has the same protocol stack RA1'-FEC-FEC-RA1'-RAA-RAA-RA2-RA2-RA1 shown in FIG. 4 for one traffic channel, between MS / TAF and 5 MSC / IWF. The protocol structure of the HSCSD traffic channel in accordance with the GSM recommendations is illustrated in Figure 5. Thus, the HSCSD traffic channel in accordance with the GSM recommendations will continue to use a common RLP for the various Osaka channels, although the bit rate of a single subchannel may be up to 64 kbit / s.

As previously stated, solutions are being developed for the GSM system that allow data rates of up to 64 kbit / s per time slot or data rates of more than 64 kbit / s in the Multi Time Interval Constellation (HSCSD). However, this development does not affect the protocol structures shown above. just the traffic channel bit rate. Thus, the GSM-recommended HSCSD traffic channel will continue to use a common RLP for 15 different subchannels, although the single subchannel bit rate may be up to 64 kbit / s and the total HSCSD traffic channel rate is n * 64 kbit / s.

Such a n * 64 kbit / s GSM traffic channel would also allow the previously described high speed access to the TCP / IP network, if supported by the mobile network.

One possibility investigated by the inventor for implementing multilink-PPP travel in communication networks is shown in Figure 6. This solution is a rather straightforward combination of the known solutions of Figures 1 and 2. The MS-IWF connection (n * 64 kbit / s traffic channel) uses the radio link protocol RLP (or the corresponding link access control protocol LAC) and the PPP only protocol over the RLP 25 (or LAC.n), as in the figure. 2 for a single 64 kbit / s traffic channel The portion between the IWF and the IAP server with two or more 64 kbit / s slots uses the multilink PPP protocol and the PPP / multilink PPP protocol mapping in the IWF, in the same way as the portion between TE and server 2 in Figure 1. Specifically, a multilink unit 6 and 30 PPP units 4 are added to the IWF so that the IWF operates in the direction of server 2 as an ISDN terminal TE. but there are no flow control mechanisms in PPP, another protocol 60 and 61 having a flow control mechanism (such as ITU-T V.120) must exist under PPP 4 and 5 between the IWF and the IAP server. for a single 64 kbit / s channel, ku 2. Although the concept of Fig. 6 is workable, according to the inventor, it presents significant problems and is therefore not practical in practice.

105976 g used. The network adapter IWF must support two new protocols, i.e. PPP only (in the MS direction) and multilink PPP (in the IAP server direction), and perform the matching between these protocols. These protocols are not supported by current IWFs on mobile networks because they are client (server) Internet protocols between client and server. In addition, when additional flow control protocol is required under PPP, the total number of protocol operations in IVVF increases significantly. As a result, 1) the complexity of the IWF increases, 2) the processing load of the IWF increases, 3) the memory consumption in the IWF increases, and 4) the mobile network becomes dependent on the development of Internet protocols.

Preferred embodiments of the present invention will now be described with reference to Figures 8-11. According to the basic principles of the invention, the traffic channel of a mobile network is divided into as many subchannels or sub-traffic streams as the connection portion between the IWF and the IAP server has 64 kbit / s time slots (channels). Each 64 kbit / s time slot or 15 channels of a fixed network connection as well as its PPP payload is matched to the allocated mobile channel subchannel or downstream such that the PPP payload is transmitted as such over the entire end-to-end connection between the multicast between. This avoids placing PPP and multilink PPP protocols in the IWF network adapter.

Further, the multilink PPP protocol in the mobile station MS is typically located in a separate integrated terminal part TE, which is generally a virtually personal computer PC. Implementation of the multilink PPP protocol for the data terminal TE already exists because ISDN networks support multiple 64 kbit / s connections and Internet access servers connected to ISDN support 25 multilink PPP connections , as previously described in Figure 1. When such a TE is coupled or integrated with a mobile network terminal MT (Mobile Terminal) which includes radio components and other features required by the mobile network, including a traffic channel division into subchannels or sub-streams according to the invention, a mobile station MS supporting the present invention is obtained. Thus, the term mobile station MS means: in this application, generally, both the case where the TE and the MT are integrated into one unit and the case where the TE is a separate unit connected to the MT.

There are a number of ways to divide a traffic channel of a mobile network into subchannels or undercurrents. Some of these ways are described in more detail below.

«M 10 105976

One way of forming n pieces of PPP subchannels or PPP sub-streams through a mobile communication network is by physical separation using separate traffic channels or sub-streams of the mobile communication network below. One or more physical downstream or subchannels (e.g., 2 * 28.8 kbit / s enhanced GSM data rate channel 5 may constitute one PPP downstream or one PPP subchannel. A separate L2R / RLP is formed for each PPP downstream or PPP subchannel (or more generally, a Link Access Control Protocol, LAC. This embodiment is illustrated in Figure 7.

The TE part of the mobile station MS comprises a TCP / IP pro-protocol unit 8 10 and a multilink protocol unit 6 and n PPP protocol units 4, ... 4, which implement, for example, a multilink PPP protocol according to RFC1990 in the direction of the server 2. The TE may thus be very similar in basic implementation to the fixed network TE shown in Figure 1. Similarly, the server 2 includes a TCP / IP protocol unit 9 and a multilink protocol 7 and n 15 PPP protocol units 5, ... 5 ,, which implement, for example, a multilink PPP protocol according to RFC1990. In addition, there is one V.120 unit 61, ... 61 for each PPP link. Thus, server 2 can be implemented on the same principles as in Figures 1 and 2. Thus, at the multilink PPP protocol level, n pieces of PPP link PPP, ... PPP 'are transferred between TE and server 2.

Each PPP link PPP, -PPP 'from the terminal TE is coupled to its own L2R / RLP unit 71, -71 ,, in the MS MT section of the mobile station. In turn, each L2R / RLP unit 71 is connected to its own speed adaptation unit RA73, ... 73 „. Each rate adaptation unit 73, -73n has a corresponding rate adapter unit 74, -74n in the network adapter IWF in connection with the mobile services switching center MSC. Between each of the '25 speed adapter pairs 73 and 74, there is a rate-adjusted data connection according to the GSM recommendations, which may consist of one or more GSM subchannels or downstream (cf. one GSM traffic channel or HSCD traffic channel). In the IWF, each speed adapter unit 74, -74 "is connected to its own L2R / RLP unit 72, ... 72". Between each pair of L2R / RLP units 71 and 72 30, a dedicated RLP link or generally a LAC link is set up. Each RLP link 'forms a kind of subchannel along which the corresponding payload of the PPP link can be transmitted. These subchannels according to the invention are referred to as PPP subchannels, or PPP data streams flowing through them, as PPP downstream streams. Further, in the IWF, each L2R / RLP unit 72, -72 "is coupled to a fixed network transmission protocol 35, ... 60", which supports the V.120 protocol or other protocol with flow control. Each unit 72 supplies to the respective unit 60 11 105976 the same PPP payload data received by the corresponding unit 71 from the terminal T in the mobile station MS. Each protocol unit 60, -60n sets up a V.120 link with its corresponding protocol unit 61, -61n via channels ch, -chn. Between units 61, 61 'and PPP protocol units 5, -5n, the same PPP signals PPP, -PPPn occur again than PPP signals occurring between units 71, -71n and 4, -4n in the mobile station MS. Traffic in the opposite direction of transmission takes place in a similar manner. This allows a connection to be made through the mobile communication system that transmits the multilink PPP protocol signals "transparently" over the mobile communication network, without the IWF 10 of the Network Adapter having to support or fit between the PPP protocol or the multilink PPP protocol. and MS do not substantially increase the processing load since each RLP unit operates at only partial speed compared to a normal common RLP unit, but it should be noted that the present invention has a significant deviation from established practice and current GSM recommendations in that a plurality of separate RLP protocol units are used instead of a single RLP unit as described with reference to Figure 5.

Another way to implement division into PPP subchannels is by physical separation by multiplexing on one broadband (> 64 kbit / s) traffic channel, e.g., TDMA / CDMA or CDMA. This broadband channel is divided into subchannels using a traffic channel frame structure, e.g., dedicated bit frames. Again, a separate L2R / RLP link (or LAC link) is used for each PPP link. Thus, one possibility to implement multiplexing is to identify the individual RLP / L2R links with a tag in the frame structure and to transmit them mixed in one broadband channel. This embodiment will be explained in more detail with reference to Figure 8.

In Fig. 8, the server 2 and the terminal part TE of the mobile station MS may be the same as in Fig. 7. The MT section of the mobile station MS has a separate L2R / RLP unit (or e.g. LAC unit) 81, ... 81n, ... 71n in Figure 7. Each L2R / RLP unit 81, -81n is coupled to a corresponding I / O port in multiplexer and demultiplexer unit 83. Multiplexer and de-multiplexer unit 83 multiplexes RLP frames from units 81, -81n into one Although the units 83 and 85 are shown separately in FIG. 8, they may also have been integrated into the same unit 35. In this embodiment of the invention, the multiplexer 83 multiplexes the RLP frames received from the L2R / RLPs 81, -81 to broadband transport frames, e.g., RLP frames of each PPP link to certain bit positions in the transmission frame. V.110 frames are transferred between RA1 adapters, and certain data bits can be allocated to each PPP link in these V.110 frames. The RA-5 unit 85 establishes, via a broadband traffic channel, a GSM-recommended rate-matched data connection with another RA unit 86 located a broadband traffic channel may be, for example, an HSCSD traffic channel or a broadband traffic channel 10 for third generation mobile communication systems.RU unit 86 outputs a multiplexer, multiplexer, and multiplexer 84, received multiplexed signal received from a mobile station MS. demultiplexes the RLP frames of each PPP link separately and supplies them to the corresponding L2R / RLP units (or LACs) 82, -82n. The 82r82n units extract the payload from the PPP from the RLP frames and supply them to the fixed network protocol unit-15 sizes 60r60n. The units 60 are similar to those of FIG. 7 and the extension connection to the server 2 also operates in the same way. Traffic in the opposite direction of transmission takes place in a similar manner.

Thus, also in FIG. 8, there are n subchannels formed between the multiplexers 83 and 84, each of which forms an L2R / RLP link. These 20 subchannels are PPP subchannels according to the invention, through which PPP data can be transmitted over a mobile communication network without the functions of the PPP protocol or the multilink PPP protocol in IWF.

Yet another way to implement multi-link PPP over a mobile network is to use a single L2R / RLP link (or LAC link) between the MS and the IWF to carry all PPP links over the PPP subchannels of the invention. These subchannels are formed by performing PPP subchanneling within this L2R / RLP link. The traffic channel below may be a single traffic channel having a sufficiently high bit rate (e.g., a third generation mobile network having a WCDMA or TDMA / CDMA channel), or the traffic channel may consist of multiple subchannels / sub-streams (e.g., GSM This embodiment will be described by way of example with reference to Figure 9.

In Fig. 9, the server 2 and the terminal part TE of the mobile station MS are structurally and functionally similar to those of Figs. 7 and 8. PPP links 35 from the terminal PP of the PPP 1 -PPP are provided to the multiplexer and demultiplexer unit 91 in the MT. The multiplexer and demultiplexer unit 91 multiplexes the data of the PPP-13 105976 links into a single signal which is output to a common L2R / RLP unit (or LAC unit) 93, where the multiplexed data is placed in RLP frames or LAC data field. In this way, all PPP links in PPPrPPP are multiplexed into frames of a single RLP link. In practice, the functions of units 91 and 93 can also be integrated such that the L2R / RLP unit performs multiplexing (and de-multiplexing) while generating (decoding) RLP frames. The L2R / RLP unit 93 supplies RLP frames to the rate adapter unit 85. The RA unit 85 has a rate matched data connection (e.g., according to GSM recommendations) with another RA unit 86 disposed in the network adapter IWF. The RA-10 unit 86 feeds the RLP frames to the L2R / RLP unit 94. The unit 94 extracts the multiplexed data from the RLP frames and feeds it to the multiplexing and demultiplexing unit 92. The unit 92 demultiplexes associated with each PPP link ΡΡΡ, -ΡΡΡ ,, data and supply them to the 60r60n fixed network protocol units. The units 60, as well as the extension connections to the server 2, are similar to those in Figures 7 and 8. The communication in the opposite transmission direction takes place in a similar manner.

In the embodiment of Fig. 9, n-multiplex PPP subchannels are formed between the multiplexing and demultiplexing units 91 and 94, which are multiplexed into RLP frames (or LAC frames). This enables the multilink PPP connection 20 to be "transparently" transmitted over the mobile communication network without the need for PPP or multilink PPP functions or adaptations between them in the IWF.

Multiplexing PPP links ΡΡΡ, -ΡΡΡ ,, for an RLP link (or LAC link) can be done in a number of different ways. Figure 10 illustrates one embodiment of the invention. 25 pairs where each RLP / LAC frame carries information from each PPP link. Assume that the number of PPP links is two, i.e., n = 2. In the data field of each RLP / LAC frame, the PPP payload (PPP1 DATA) of the first PPP link is placed at certain bit positions, and the payload (PPP2 DATA) of the second bit positions. From the PPP link PPP2.

Figure 11, in turn, illustrates the case where each RLP / LAC frame carries information from only one PPP link at a time. Again, suppose you have two PPP links. A payload (PPP1 DATA) of the first PPP link PPP is placed in the data field of each second RLP / LAC frame, as well as a link identity LINK ID which indicates to which PPP-35 link the data in that RLP / LAC frame is associated. Similarly, a payload (PPP2 DATA) of the other 14 105976 PPP links PPP2 and a link identifier LINK ID are placed in each of the other RLP / LAC frames. For example, the link identifier may be a numeric value at the beginning of a data field, as in Figure 11. The multiplexing principles of Figures 10 and 11 can be applied to any number of PPP links.

Preferred embodiments of the invention have been described above. It will be appreciated that alternative solutions and modifications will be apparent to those skilled in the art and may be practiced without departing from the spirit and scope of the appended claims.

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Claims (24)

A mobile communication system comprising a mobile telephone (MS) and a network adapter (IWF) for forming an end-to-end high-speed data connection or a data network access point (2) supporting a multi-link point-to-point protocol PPP, said end-to-end connection comprising a first connection part between the mobile telephony (MS) and the network adapter (IWF), which uses a control protocol for link access LAC in the mobile telephone network, such as the radio link protocol RLP, and a second multi-link PPP connection part (the network adapter) and the access point (2), characterized in that the mobile telephony (MS) comprises multi-link PPP protocol means (4, 6) to form at least two PPP links (PPP1, PPP) with said access point (2) through said end-to-end connection. , the connection portion between the mobile telephony (MS) and the network adapter (IWF) comprises at least two PPP subchannels for transmitting each of said at least two PPP links (PPP1, PPP) in their own PPP subchannel, the network adapter (IWF) is arranged to adapt each PPP subchannel to the corresponding PPP link (PPP1, PPPn) through said multi-linked PPP connection, so that PPP The links are translucent between the multi-link protocol means and the access point (2). Mobile communication system according to claim 1, characterized in that there is a separate LAC link between the mobile telephony (MS) and the network adapter (IWF) and a physically etched traffic channel or traffic stream for each PPP link (PPP1, pPPN). Mobile communication system according to claim 1, characterized in that there is a separate LAC protocol link for each PPP link (PPP1, PPPn) and a common broadband traffic channel for all PPP links (PPP1, PPPn) and that the mobile telephone (MS) and the network adapter (IWF) are arranged to multiplex the PPP links (PPP1, PPPn) to said broadband traffic channel. ·· 4. Mobile communication system according to claim 3, characterized in that the mobile telephony (MS) and the network adapter (IWF) are arranged to multiplex the PPP links (PPP1, PPPn) to a broadband traffic channel's frame structure. Mobile communication system according to claim 4, characterized in that each PPP link has predetermined bit locations in the transmission structure of the broadband traffic channel. Mobile communication system according to claim 4, characterized in that the mobile telephony (MS) and the network adapter (IWF) are arranged to multiplex the frames for each separate LAC protocol link to said broadband traffic channel. Mobile communication system according to claim 1, characterized in that a common l_AC protocol link exists for all PPP links (PPP1, PPP) between the mobile telephone (MS) and the network adapter (IWF) and the PPP subchannels are multiplexed within the LAC. -protokollänken. Mobile communication system according to claim 7, characterized in that each frame for LAC protocol links contains information about each PPP link (PPP1, PPPn). 9. Mobile communication system according to claim 7, characterized in that each frame for LAC protocol links contains information about only one PPP link (PPP1, PPPn) and information about where the PPP link's information relates. Mobile communication system according to any of claims 7-9, characterized in that there is a common broadband traffic channel between the mobile telephony and the network adapter. Mobile communication system according to any of claims 7-9, characterized in that the traffic channel under said common LAC protocol link, which lies between the mobile telephony (MS) and the network adapter (IWF), consists of two or more sub-traffic channels. A mobile telecommunications system for mobile communication, comprising mobile means for forming an end-to-end high-speed data connection in a data network access point (2) supporting a multi-link point-to-point protocol PPP, said end-to-end protocol end connection comprises a first connection part between the mobile telephony (MS) and the network adapter (IWF), which uses a control protocol for link access LAC 30 in the mobile telephone network, such as the radio link protocol RLP, and a second multi-linked v. PPP connection part and between these a network adapter (IW) characterized in that the mobile telephony (MS) further comprises multi-linked PPP protocol means (4, 6) for forming at least two PPP links (PPP1, PPP) through said end-to-end connection with said access point (2) , means (71, 73, 83, 91) for placing said at least two PPP links (PPP1, PPPs) in two or more corresponding number of PPP subchannels on said first connection part for transmitting each PPP link in its own subchannel. The mobile telephony patent claim 12, characterized in that the mobile telephony (MS) comprises means (71, 73) for forming a separate LAC link and a physically etched traffic channel or traffic stream for each PPP subchannel on said first sub-connection. Mobile telephone apparatus according to claim 12, characterized in that the mobile telephone apparatus (MS) comprises means (81) for forming a separate A LAC protocol link for each PPP link (PPP1, PPPn) through a common broadband traffic channel and means (83) for multiplexing the PPP links to said broadband traffic channel. Mobile telephone apparatus according to claim 12, characterized in that the mobile telephone apparatus (MS) comprises means (93) for forming a common LAC protocol link for all PPP links (PPP1, PPPn) and means (91) for multiplexing the PPP subchannels within the LAC protocol link. A network adapter for the mobile telephone network, which network means comprises means for forming an end-to-end high-speed data connection in a data access point (2), which supports a multi-link point-to-point protocol PPP, and between the mobile telephony (MS). ), said end-to-end connection comprising a first connection part between the mobile telephony (MS) and the network adapter (IWF), which uses a control protocol for link access LAC in the mobile telephone network, such as the radio link protocol RLP, and a second multi-linked PPP connection part between The network adapter (IWF) and the access point (2), known - 25. characterized in that the network adapter (IWF) comprises means (72, 74, 84, 92) for placement of the multi-linked PPP connection part's PPP links (PPP1, PPPn) ) in the corresponding number of PPP subchannels on said first connection portion for transmitting each PPP link in its own PPP subchannel, such that the PPP links run transparently through 30 network adapters n between the mobile telephone (MS) and the access point (2). Network adapter according to claim 16, characterized in that the network adapter (IWF) comprises means (72, 74) for forming a separate LAC link and a physically separate traffic channel or traffic stream for each PPP subchannel on said first sub-connection. Network adapter according to claim 16, characterized in that the network adapter (IWF) comprises means (82) for forming a separate LAC protocol link for each PPP link (PPP1, PPPn) through a common broadband traffic channel and means. (84) for multiplexing the PPP links to said broadband traffic channel. Network adapter according to claim 16, characterized in that the network adapter (IWF) comprises means (94) for forming a common LAC protocol link for all PPP links (PPP1, PPPn) and means (92) for multiplexing PPP sub-channels within the LAC protocol link. A method of forming an end-to-end high-speed data connection, the method comprising the stage, wherein a first connection part is formed between the mobile telephone and the network adapter in the mobile telephone network, a second multi-channel connection part is formed between the network adapter and the second part, characterized the method further comprising the stages, wherein a multi-link end-to-end connection is formed between the mobile telephony and the other party, the subconnection between the mobile telephony and the network adapter is divided into sub-channels, each link in the multi-linked end-to-end connection. the end connection is transmitted in its own sub-channel in the sub-connection between the mobile telephone and the network adapter. 21. A method according to claim 20, characterized in that on the sub-connection between the mobile telephony and the network adapter 25 a separate link access control protocol (LAC) is formed, such as a radio link protocol (RPL) link, and a physically separate traffic channel or traffic stream. each link for a multi-link end-to-end connection. Method according to claim 20, characterized in that on the sub-connection between the mobile telephony and the network adapter 30 a separate link access control protocol (LAC), such as a radio link protocol (RPL) link, is formed for each link for a link. multi-link end-to-end connection, on the sub-connection between the mobile telephony and the network adapter, a common broadband traffic channel is formed for all links for a multi-link end-to-end connection. 23. A method according to claim 20, characterized in that on the sub-connection between the mobile telephony and the network adapter a separate link access control protocol (LAC), such as a radio link protocol (RPL) link, is formed for each link for a link. multi-link end-to-end connection, on the sub-connection between the mobile telephony and the network adapter, a common separate link access control (LAC) protocol link, such as a radio link protocol (RPL) link, is formed for each link for a multi-link end-to-end connection, the links for a multi-link end-to-end connection are multiplexed within the LAC protocol link. The method according to any of claims 20-23, characterized in that said multi-link end-to-end connection uses a multi-link point-to-point protocol PPP and that each link of the multi-link point-to-point The point link uses the point-to-point protocol PPP. 15