FI119089B - Dynamic heterogeneous network system for e.g. internet browsing, has five building blocks including mobile host, access network, network node, authentication-authorization-accounting node and external network - Google Patents

Abstract

The system has building blocks including mobile host (1), access network (7), network node (2), authentication-authorization-accounting (AAA) node (13) and external network (3). The interfaces enable access of network node and access network, with respect to the host. The building block of network node has AAA protocol interface function, control logic function and traffic routing function. Independent claims are also included for the following: (1) network node; and (2) mobile host on heterogeneous network system .

Description

119089 i

A mobile host in a dynamic and heterogeneous network system for communication systems

The invention relates to a system which functionally connects a plurality of telecommunication networks in order to increase the overall performance and overall capabilities of the heterogeneous network system. In particular, the invention relates to a method for providing a mobile host entity to achieve the support for a heterogeneous network described in claim 1.

Despite the existence of a significant number of stakeholders globally with the common goal of minimizing the number of different network technologies used in the market, there is today and in the foreseeable future a large number of wired and wireless systems used and standardized either locally or globally. .

Some of these network technologies date back to the past and may have undergone a significant amount of extensive improvement and optimization activities during their life years, while other network technologies are still in the early stages of their life cycle and may rely on the use of highly advanced new methods to meet their requirements.

Some of the above new methods may have been impossible to implement in commercial ·· «V! in products before recent advances in, for example, circuit technologies and ·· • 1 2 1 computing platforms have become available.

· · · · · · · · · · ... 2 The requirements for different network technologies also have a major impact on how ambitious systems are implemented in M1 - · · ί - some of them have been developed · 3 · ***** virtually anywhere on the globe with up to 99.999% availability requirements over time and data rates of tens of t · · · · · kilobits per second, some of which are designed to cover a small personal area at extremely low cost and low power consumption. With a data transfer rate of up to hundreds of megabits per second, the rest of the systems settle between these two extremes. . Also, some systems are optimized for circuit switched services such as voice, while others are optimized for packet switched services such as Internet browsing, computer networks, and email.

The fragmented situation described above, coupled with the fact that each internationally standardized mobile phone system generation is significantly more complex and costly to develop than its predecessor mobile phone system generations, and development in every system generation. One possibility is to use existing and new technologies together, which is the trend in 4G research and standardization, and to allow the overall system to use the features best suited to the specific traffic situation in a balanced way, thereby achieving economic and technical synergies. The present invention describes such an approach.

Current state of the art is that there are a number of access network technologies, both wired and wireless, examples of wireless systems are cellular network systems (NMT, GSM, AMPS, CDMA, PDC, GPRS, EDGE, WCDMA, CDMA-2000, Inmarsat) and examples of wireless network systems are: Standards: T: Standards developed to meet the needs of a limited service area (WPAN, WLAN, WMAN, WBMA, UWB, Bluetooth, ZigBee, Infrared). Then there are a number of ·· · • V wired access network technologies, such as ADSL, SDSL, VDSL, Cable ··· TV based systems, modem systems in the telephone network, HomePNA, FTTH. There have also been several attempts to connect cellular networks and * ·· · ... * LANs using different methods. The common denominator for these mentioned methods is that they are based on cross-system location tracking or even • · * »t! ·! · Inter-system handover (also known as vertical handover) so that users can be served in the most appropriate way. Well * 9 9 9 9 9 9 9 9 9 999 9 9

9 I

The advanced approach in this field is described in US 2003/0048762 AI, US 2003/0048773 AI, US 2003/0050061 AI, and in patents (JP) 2001-272660,2001-272661, 2001-317471 wherein a plurality of wireless communication systems are seamlessly interconnected using a separate basic access network to interconnect different systems together and utilizing SDR technologies to enable mobile host communication with different wireless systems, essentially one at a time, horizontally handoffs. The system described in the above patents is also known in the literature as the MIRAI architecture. A valuable reading of the prior art is the use of the known IETF SIP protocol for heterogeneous networks in Schultzrinne et al., 'Multimedia SIP sessions in a Mobile Heterogeneous Access Environment'. S. Mangold has written an extensive paper on 802.1 Service Level Issues in his dissertation: 'Analysis of IEEE 802.1 Application and Game Models for Support of Quality-of-Service in Coexisting Wireless Networks'.

It will be obvious to one skilled in the art that providing a comprehensive description of the state of the art in such an enormous area, which is also going through a breakthrough that has never been seen in telecommunications history, is difficult, especially if it is to be brief. The documents listed above are selected with a view to providing the reader with a very simple overview of the situation.

The invention enables a random amount of heterogeneous traffic to be accessed over networks (wireless or wired) at the same time, and connections are reorganized functionally as needed to maintain the service level of the end user. To: '·': Initially connect to the user, use mobility management: 1 \, authentication and authorization functions available in known j 2 1 2: existing network access, thus eliminating the need to build an expensive stand-alone ··· access network only for this purpose. Also, a mobile host is a concept that combines ..3 multiple mobile host units, each with different capabilities, and which • · · communicate with each other. The invention also avoids inter-system (also known as vertical) power exchanges because they are very expensive and complex to develop, test and use with sufficient reliability, and the invention is based on conventional connection setup ***** • · · • 1 • · 1 • · »* 1 ··· • 1 · · 1 · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · 119089 is being reorganized.

Also, a mobile host with access to a heterogeneous network is a master control unit for traffic control on that heterogeneous network, this implementation has many advantages when compared to known heterogeneous networks using more centralized traffic control methods, namely (re-) intercepting decisions, the arrangement functions must be performed, and thus significant savings in signaling over the limited bandwidth access interfaces can be achieved, and smaller delay times in response times can also be achieved. Trends in circuit technologies and computing platforms, as well as advances in digital radio signal processing research, indicate that more efficient and functionally advanced handheld systems are coming to the market, and in this sense it is a natural development to move more computing responsibility closer to the network. Another notable advantage that can be achieved when a mobile host controls traffic routing in a heterogeneous network is that the overall system robustness (robustness) can be greatly increased, since access networks in many cases overlap and a service disruption to the user would require multiple simultaneous problems in different parts of the system. the approach significantly reduces the likelihood of such a situation compared to known: V: networks.

♦ · * · • · »M · • As the mobile host plays a key role when it comes to detecting the deterioration of traffic quality ··· ::, recovery measures can be initiated immediately, which is ... ί a very important factor in increasing the system's overall strength and quality. · * · · · '' To minimize the duration of weakening. Also, the transfer of control responsibility in the architecture of the heterogeneous network according to the invention to the mobile host • · · * ”/ makes it possible to develop the system so that there is no need to store persistent subscriber-based information such as traffic nodes involved in traffic routing. 119089 5 lack of the need to store subscriber-based information from network nodes involved in the routing of the interface facilitates network installation and deployment. use significantly.

One advantage of the invention is to use the standard rigid system components as much as possible, and to minimize the number of changes required. This fosters competition and makes the deployment and use of the overall system cheaper.

The features of the invention are described in claim 1.

The following is a description of the drawings used.

FIG. 1 is an illustrative architecture view illustrating how a heterogeneous network is comprised of individual access networks, and how a mobile host, access networks, a network node, and an external network are connected in a heterogeneous network.

FIG. 2 is an illustrative view of the internal architecture of the mobile host.

FIG. 3 is an illustrative architectural view of how a mobile host and a network node are connected over a heterogeneous network. The interfaces to the external network and to the AAA (authentication, authorization, and billing) node are also illustrated.

FIG. 4 is an illustrative view of the internal architecture of the network node.

· * · • · 0 i · · • FIG. 5 is an illustrative architecture view of the interfaces between the network node and the internal host • 0 ·: V of the mobile host.

···:: · * · „1: * FIG. 6 is a signal diagram example of setting up a network-initiated connection period ** · * in a heterogeneous network using a GPRS network service for establishing a initial connection between a mobile host and a network node.

S · * · • 0 0 000 · 000 • 0 • · 000 • • 0 0 0 * 0 0 · • · 00 · 0 0 • · • 00 0 0 · • 0 0 • • 0 000 0 0 · 0 ·· 0 00 0 0 119089 6 FIG. 7 is a signal diagram example between a mobile host and a wireless access network access point; in this case, the access point is an 802.1 lx WLAN AP that supports the principles of service level mechanisms as defined in 802.1 le.

FIG. 8 is a graphical representation of FIG. 7 for details of signaling over a physical radio interface.

FIG. 9 is an architectural description of the data structures of a mobile host control and measurement database function.

FIG. 10 is a signal diagram example of a procedure in which an existing connection in one access network is re-routed to another access network triggered by detection of a degraded service level (QoS).

The following numbering is used to identify the entities used in the pictures: 1 Mobile Host, 2 Network Node, 3 External Network, 4 Mobile Host X, 5 Mobile Host Y, 6 Interface between Mobile Host X and Y, 7 Network Access, AC Access Networks with Mobile Host X has the capability to communicate, ac access interfaces to the above networks, DG Access networks with which the Mobile Host Y has the capability to communicate, dg access interfaces to the above networks, 8 Mobile Host Controlling Logic Functions, O: Applications that use heterogeneous network services, 12 Access networks ··· 1 ·· Access points (including access points or wired access methods), 13 A AA - Authentication · · ·: V Authorization and Billing Node in a heterogeneous network, 14 AAA - Authentication, Authorization and • · ·

Your Billing Interface Function on a Network Node, 15 Network Node Control Logic Function, 16 «·· ···· Network Node Traffic Routing Function, 17 GPRS Gateway Support Node (GGSN), 18 '··· 1 Home Subscriber Register (HLR), 19 GPRS PDUol, 18 Send Routing Information (SRI) Message for GPRS, 22 MAP Send Routing Information • · · *** .. 1 (SRI) Acknowledgment Message, 23 PDU Notification Request Message, 24 PDU Notification Response Message, 25 • ♦ • · '1' PDP Reference Frame Activation Request Message, 26 PDP Reference Frame Activation Procedure, 119089 7 27 The Connection Establishment Procedure ( PAN), 28 Procedure for Scanning and Identifying Access Networks to be Used, 29 Message Conveying Information on Available Access Networks, Their Service Level Properties, and Mobile Host Control and Measurement 30 message transmitting the access network candidate list, service level agreements on each access network, and authentication information on each access network, 31 a procedure whereby a mobile host registers on the access network using information obtained in 30, and receives the identifier, which forwards user identifiers, connection service level information, and control information retrieved from the mobile host control and measurement database, 33 forks SIP INVITE for user identifiers, 34 Procedure for setting up connection cycles between external network and user identifiers, 35,802.1 lx Access Point (AP), 36 Message for Forwarding credentials and service level information request information used in that access network, 37 A procedure for authorizing a user and analyzing a service level request, 38 Response message to 36, including information about what is available service levels, 39 Message to select the final service level to be used, 40 Procedure for establishing connections, service level control and measurement handshaking between Mobile Master Y5 and Access point 35, 41 Intermittent CAP QoS CF poll containing results of service level measurement performed at Access point AP 35, 42 Stores 41 measurement results in the Mobile Host Control and Measurement Database 10.43 CF-ACK containing the results of service level measurements performed by the Mobile Master Y 5, 44 Access point AP 35 processes 44 data, 45 Procedure example where periodic service level handover is implemented in 802.1 le 802.1 In a WLAN environment, 46 Target Beacon Transmission Time (TBTT), 47 • 1 ·· Beacon, 48 QoS CF-Poll, 49 Transmission Request (RTS), 50 Clear to send (CTS), 51 Data ·· · ϊ (MSDU), 52 Data (ACK), 53 CF-end, 54 Contention Free Period (CFP), 55 Contention • · * ... 1 Period (CP) , 56-63 different access networks, 64 different access network target areas ··· • · ·; (for example, network operators) for each access network technology, 65 single · 1 · '· · ·' access network instance records, 66 highest service level records, 67 higher service level records, 68 medium service level records, 69 lower service level records, 70 service level is found to be below its requirements, 71 Connection redirection message, 72 Procedure in which: • ♦ ♦ »» • 1 1 • • • • 11 11 11 11 11 11 11 11 11 11 11 11 11 11 11 11 11 11 11 11 11 11 11 11 11 11 11 11 11 11 11 11 11 11 11 11 11 11 11 11 11 11 11 11 11 11 11 11

In the following, the invention has been illustrated by means of preferred embodiments.

In order to achieve the above objectives, the invention utilizes the following means:

In a heterogeneous network that connects communications systems, a common network node that supports multiple access networks, performs traffic, and authentication, authorization, and billing functions in collaboration with the Mobile Master.

The heterogeneous network system allows the Mobile Host to roam simultaneously on multiple access networks, utilizes the existing mobility management and authentication / authorization functions of the access networks to locate the roaming mobile host and establish a initial connection between the mobile host and the network node.

The mobile host is capable of simultaneous communication over multiple access networks, and these networks may consist of either wired or wireless access networks.

The established initial connection between the network node and the Mobile Master performs authentication and authorization of the subscriber to the heterogeneous network, and multiple concurrent connections are established over multiple access networks. The Mobile Host is authenticated and · 1 · 1: authorizations are granted to each access network based on the initial access information, and the identities used by the Mobile Master on each access network are reserved: 1 2: enabled and stored on the Mobile Host and passed on during connection • aa ί, ϊ connections. The actual establishment of the requested connection cycles, .1 · 1 is based on the service level requirements for the connection, the user-owned ·· 1 • ..S credentials on the heterogeneous network, and the control information stored in the Mobile Host.

• • • • • • • • • • • • • • • • • • • • • • • • • • • • • • • • • • • • • • • • aa1 a · 2 · · aa1 a · 2 · · aa1 a · 2 · · aa1 a · 2 · 119089 9

The mobile host and the access network reciprocal entity monitor the service level of the established connections, and the resulting information is transmitted to the mobile host for use in making connection and re-routing decisions in each case. The service level is measured locally by the Mobile Host and the access network reciprocal entity, and the end-to-end service level is measured by the application. The results of local service level measurements are used to make decisions about re-routing of connections on a heterogeneous network during traffic transmission. Changes in the perceived end-to-end service level will result in applications responding accordingly.

Service level is measured by data throughput, data transmission delay, data vibration, invalid packet level, and lost packet level. Service level requirements for connections are a subset of these, plus a service level benefit class.

The basic principle used in connection rerouting is to use the connection establishment and releasing mechanisms when rerouting a particular connection via an alternate bus when using the system. This procedure eliminates the need to create complex handover mechanisms between numerous access network technologies. Applications are relayed with information about rerouting so applications can initiate corrective actions if they need to.

• · · :: The heterogeneous network system is based on the fact that horizontal handoffs ·· •: 1 1 are executed on each access network without the need for a heterogeneous network-level intervention, provided, for example, that service level requirements become • · * · ·; 1 completed.

The invention has been described with reference to the drawings.

1 · * "/ Note that the access network technologies used in the drawings are wireless," but wired access network technologies may also be used in the invention. · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · ·

The architectural relationships between the blocks of the heterogeneous network can be seen in FIG.

1. As can be seen in FIG. 1, Mobile Host (1) communicates with a plurality of access networks (7, A-G), (a-g), which are connected to a network node (2) and an external network (3). Due to technical drawings, only the access networks (A) and (G) are directly connected to the external network (3), any number of access networks (7) can be connected to the external network (2) in the icing arrangement according to the invention.

FIG. In 1, the Mobile Host (1) consists of two Mobile Hosts, a Mobile Host X (4), and a Mobile Host Y (5). The invention does not limit the number of Mobile Hosts, which are characterized by their capability to support a subset of supported network access technologies in a heterogeneous network in any way; these devices only need to be capable of supporting the functionality of a heterogeneous network architecture. For example, Mobile Host X (4) may be a multiband mobile device with GSM / GPRS / EDGE / UMTS, etc. capabilities and Mobile Host Y (5) may be a computer terminal equipped with a plurality of WLAN / WMAN / WBMA / UWB, etc. capabilities and Mobile Host Interfaces ( 6) Can be, for example, a wired, infrared, Bluetooth, ZigBee or internal device interface.

FIG. 2 depicts the Mobile Master's internal architecture. Applications (11) ···: Provides heterogeneous network services with access to control logic functions (8) and access to ·· • * ·· traffic routing functions (9). The control logic function (8) is responsible for · · · · · · · · · · · · · · · · · · · · about establishing, decompressing, and rerouting connections in a heterogeneous network, and ···

The traffic routing function (9) takes care of the actual traffic flow routing ···. ··! According to the controls of the control logic function (8). The Control and Measurement Database (10) t ·· · · · · · · · provides control Control function (8) and Traffic routing function (9) with control parameters and service level measurement results. Mobile Hosts (X) and (Y) t · · communicate with Access Networks (A-C), (D-G). Access Network Transfer Layer (MAC) layers provide connection service levels on the access networks, and execute • · m · · «· ·

• M

9 · • ♦ · »« • • • ♦ «» · ··· · f · • «t 9 M • · 11 1 1 9089 service level measurements in those access networks. The results of said service level measurements are respectively stored in the Mobile Host Control and Measurement Database (10).

FIG. 3 illustrates how the Mobile Host (1) communicates with the Network Node (2) over individual access networks (7) through their wireless access points or access points or wired access points (12), and the Network Node (2) is connected to an external network (3) and AAA node. (13). Individual access networks (7) may also have direct access to the external network (3).

FIG. Figure 4 illustrates the internal architecture of the Network Node (2). The AAA node (13) communicates using the AAA protocol interface function (14) with the control logic function (15). The control logic function (15) communicates with the external network (3) and the Traffic routing function (16) which are connected to the external network (3) and access to the networks (7).

FIG. 5 has the communication interfaces between the Mobile Host Control Logic Function (8), the Network Node Control Logic Function (15), and the AAA Protocol Interface Function (14).

FIG. 6 is a signal diagram example where the initial connection to the Mobile Host is established using a GPRS network. In this example, Mobile Host X (4) has an active GPRS subscriber line and is also within range of that GPRS network.

V 1 access that network. The network node (2) transmits the PDP PDU message (20) to the GGSN

·· 5 for 2 nodes (17) that send a Cellular Telephone Part (MAP) Send a Routing Information (SRI) message ·· ·

! (· '(21) to home location register (HLR) (18) which responds back with SRI ACK acknowledgment (22) GGSN

* ··; 'to the node (17). Thereafter, the GGSN node (17) sends a PDU Notification Request (23)

• M

To the SGSN node (19) which responds back to the PDU Notification Response (24) by saying Mobile • · • ·

The host is for X (4), and the PDP reference frame activation function (26) is then performed.

. In this case, Mobile Master X (4) and Mobile Master Y (5) connect (27) and • · ·

The mobile host Y (5) scans (28) the available access networks, and sends the GGSN

• «t · 1 t ·% to node (17) a message (29) containing information on the available access networks (7) • 1 · 1 1 • 1 ·« 1 • • • • • • I »I • 1 «« «• · · · 11 90 90 90 90 90 90 90 90 90 90 90 90 90 90 90 90 90 90 90 90 90 90 90 90 90 yhdessä yhdessä yhdessä yhdessä yhdessä yhdessä 90 yhdessä 90 90 yhdessä 90 90 90 90 119089 12 together with service level property information of access networks and control information from the Mobile Master (1) Measurement and Control Database (10). The GGSN node (17) forwards the said message (29) to the network node (2). The network node (2) together with the AAA node (13) processes the content of the message (29), and responds back to the Mobile Host Y (5) by saying (30) containing a list of network access (7) candidates along with service level agreements and authentication and authorization information candidate list access network. The mobile host Y (5) registers to the access networks (7) using said information and obtains user identifiers in the access domains and service level information in the procedure (31) transmitted by the mobile host Y (5) to the network node (2) in message (32), the network node forks the SIP INVITE message (33), and connection cycles are established and the resources they require are allocated (34) in the required access networks.

FIG. 7 is a signal diagram example between a Mobile Host Y (5) and an IEEE 802.1 lx access point (35), each of which supports the service level mechanism principles of the IEEE 802.1 le extension. The details of the implementation of the service layer mechanisms used in other access networks (such as 802.16, 802.20, UWB, and UMTS PS RABs) may be different, but the principles described herein also apply to other access network technologies. The mobile host Y (5) sends a message (36) containing authorization information to said access network and service level request information to the access point (35), and the access network performs a procedure (37) verifying the user authorization and analyzing the content of the service level request.

Ml '·, · 1 The access point (35) then responds with a message (38) containing the supported available ·· i service levels and their information to the Mobile Host Y (5), which responds with (39) ti t || l:. * Where is the required service level reservation information. Then, a sequence of operations (40) is performed in which the m 9 9 * · · · * aggregates are formed and the control and measurement data of the service levels they require

M1 * ** j is handled between the Mobile Master Y (5) and the Access Point (35). During the operation of connection periods • · * ··· ', the access point performs periodic service level handshakes (45) which,. consisting of parts 41 to 44. The message (41) is a CAP QoS CF poll containing the results of a service level measurement performed by the access point (35) to the Mobile S * *** Host Y (5) stored in the procedure (42) Mobile Host Controller and • · * ··· • · • t ·· * * · · II · * · · III 9 9 · • · · 99 • · 13 1 19089

To the measurement database (10), and the message (43) is a CF-ACK including the results of a service level measurement performed in connection with the Mobile Host Y (5), which is processed (44) by the access point (35).

FIG. 8 shows in more detail how the communication is implemented between the Mobile Master Y (5) and the Access Point (35) in a frame structure according to the 802.1 le extension. The TBTT (46) is the time between the times indicated by the Beacons (47), and in the time between the Beacons (47) the non-competitive section (54) and the competition period (55) form the superframe structure. The periodic service level handshake is performed during a non-competitive period (54), which is performed at the highest level of the transmission link, which guarantees that the data transmission is accomplished in a predictable time. The sequence of actions begins when the access point (35) transmits a CF-QoS poll (48) message to which the Mobile Master Y (5) responds with a Send Request Message (RTS) (49), and the Access Point responds with a Free Send Message (CTS) (50), then the Mobile Master Y (5) transmitting its service level information in the message MSDU (51), and the access point transmitting its service level information in an acknowledgment message ACK (52), the non-competitive period ends in the CF-end message (53). Service-level traffic takes place during the competition period (55). It should be noted that the non-competitive section (54) is optional.

FIG. 9 illustrates the architecture of the Mobile Master Control and Measurement Database; in this example, blocks 56-63 represent different access network technologies. The arrow (64) represents different overlapping networks; this means that in some technologies it is possible to · * · * · * · * * join multiple access networks simultaneously if desired by the Mobile Master * · * · '' * capability, or alternatively one may choose * * · * * • · 'for use by such access networks. These different networks may, for example, be used by different operators. As an example of the access network technologies used, ··· The following may be used: (56) GSM circuit switched speech, (57) GSM circuit switched data, (58) # f GPRS / EDGE, (59) 3G WCDMA (UMTS), (60) IEEE 802.1 la, b, g it n, (61) IEEE 802.16 ,. (62) IEEE 802.20 and (63) IEEE UWB or Wired Access Network. Block (65) represents | · · ·, In more detail one database record, showing access to the structure of data stored per network • # 999. The record (65) consists of four parts, 66-69, each of which in this example 9 · · • · t 9 ··· 9 · 999 • t • ♦ · • tf ♦ * · t 9 9 9 9 9 9 * 9 9 · 14 119089 stores information about service level classes. Thus, (66) data is stored in the highest service level class, (67) is data stored in the higher service level class, (68) information is in the average service level class and (69) is in the lower service level class.

The invention does not limit the number of service level classes, there is a commonly used method of using four service level classes, and for this reason also in this example four service level classes are used. Each of the blocks 66-69 stores at least the following information: Initial values of service level parameters, measured service level parameter values for both AP and Mobile Host, Service level parameter thresholds, Service level parameter thresholds, scoring value, operator specific score coefficient and user identifier for each access point. The smallest set of service level parameters are data transfer rate, transfer delay, and transfer vibration information. The data transfer rate denotes the amount of data transmitted per unit of time per transmission, the transmission delay is the amount of time the data packets are averaged in the implementations of that access network technology (e.g., level 2 buffers) before being timed for transmission and successfully transmitted, respectively. Briefly, the values of the parameters of the above service level classes are handled as follows: The initial values of the service level parameters store service level information based on the service level agreement (SLA) from that access network, for example, from the AAA at the start of connection sessions in this network. The measured service level information is obtained as shown in the example illustrated in FIGS. 7 and FIG. 8. The thresholds for the parameters of service levels * · 1 · · .1 1 are intended to serve as a reference point for indicating whether lask 2 is calculated upwards or downwards for this particular connection. The service level parameter ·· · • f t • · 1 threshold indicates when, based on service level measurements, the connection score • · * · 1 2 should be immediately reset and the connection re-routing forced immediately.

· · ·

The scoring value is an artificial number that attempts to indicate how well the • · • · * '1 access network in question meets the service level requirements as mentioned above. If. , the service level measurement results are above the service level parameter thresholds, the S · · * “/ score is incremented up, otherwise the score is decreased down.

Also, the rate of calculation of the score in each direction is different, this is intended to be t1 · t1 · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · • • • •erate • 15 to allow for a quick recovery in case of problems with connections. An operator-specific score factor is used to provide the end user with means to set personal preference for access networks, for example based on the use of different billing policies or other reasons. The use of the scoring value during communication is as follows: When establishing a connection, the Mobile Host scans the available access networks, calculates the product of the access network scoring values and operator-specific score factors, and the access network that has the highest priority 6. If, during communication, the scoring value multiplied by the operator-specific scoring factor drops below a certain threshold value, the connection re-routing is initiated as described in FIG. 10, and if the above score multiplied by the operator-specific score factor falls below a certain threshold, the connection is immediately disconnected and any re-routing is initiated, whereas in the former case, the new connection is first established and the old connection is disconnected from the old connection. .

FIG. 10 is a signal diagram illustrating a situation where an existing connection period through one access network is re-routed to another access network due to a degraded service level. The sequence begins with the situation where said connection period (34) is established between the external network (3) and the Mobile Master (1) via the first access network access point (35). Service level measurements performed during the connection period result in ··· V 1 that the connection score multiplied by the operator-specific score factor is ** (! ** dropped below the threshold value (70), and the functions for connection re-routing ·· · • 1 »are triggered. from the network node (2) in the message (29) to the credentials * ··· for the available access network with the best scoring values, hereafter referred to as the «second access network» and then the network node (2) replies with the message (30) • · »* 1 1 containing service level agreement values for one access network, and authorization information for another access network, The mobile host (1) sends a message (36) containing authorization information for i · · "·· 1 to another access network and service level request information for another access network access point. the access network performs a sequence of steps (37) wherein eusten • 1 · * · M · · 1 · 1 · 1 · 1 · · · · · · · · · · · · · · · · · · · · · · · 16 167 19089 The analysis and authorization of the lure level request are analyzed. Thereafter, the access point (35) of the second access network sends an acknowledgment message (38) containing information about the available service levels to the Mobile Master (1), which in response sends a message (39) containing the required service level reservation information. Thereafter, a sequence of operations (40) is performed in which connection cycles are established, service level control and measurement information is handled between the Mobile Master (1) and the second access network access point (35). The mobile host (1) sends a message (71) to the external network (3), this message conveying that a new connection period has been established in the second access network. In the procedure (34), the connection period is routed from the first access network to the second access network, and in the procedure (72), the connection period of the first access network is decrypted.

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Claims (7)

A mobile host in a heterogeneous network system that unites data communication systems, wherein the heterogeneous network system supports communication via a plurality of access networks (7) between the mobile host (1) and a network node (2), wherein the mobile host is characterized in that: said mobile host (1) provides a common base for the access networks (7), said mobile host (1) being provided with: means for periodically and transaction-based measurement of service level for established in a plurality of access networks (7) in the heterogeneous network system. connections, such that the measurement of service level is carried out between a transmitter with service level readiness in the mobile host, a receiver part with service level readiness in an access network, and that said service level is measured as data transfer rate in bit / s, as data transfer delay and data transfer delay, the proportion of packet wastes in the data transfer, or as a selection of these g service level round factors, and means for including information in service level contracts in the access networks by the network node (2) in the heterogeneous network system, so that the information in the service level contracts consists of a selection of the aforementioned service level basic factors, and that the said mobile values consist of: ·· • · * [* '- a control and measurement database (10) in which the service level measurements, based on the quality of the transmission path, are based on the quality information for the transmission path and the control parameters of the control logic function (8). decision-making is stored, • · • · *** - a route determination function for traffic (9), which performs establishment, ··· * !. " route modification and disconnection measures for the protocols in a plurality of access networks (7) in the • a ♦ · heterogeneous network system, (.t - a control logic function (8), which activates the route determination function for the traffic · 9 · ) in the mobile host (1) to perform establishment, route change, and disconnect actions for the protocols of said plurality of access networks (7) in the heterogeneous network network, such that said activation is based on the said, in the control and • · • «T the measurement database (10) in the mobile host (1) stored the information on measurements of • · • · · *. * · * service level and on the information on service level contracts, and« ·· • a · · * * - support for simultaneous communication between the mobile host (1) and the plurality of access networks (7). Mobile host according to claim 1, characterized in that the mobile host (1) is adapted to communicate in the heterogeneous network system by means of an initial connection established between the mobile host (1) and the network node (2) by means of the required functionality provided by the plurality of access networks (7). Mobile host according to any of claims 1-2, characterized in that the mobile host (1) is adapted to be authenticated and authorized in the heterogeneous network system by means of said initial connection between the mobile host (1) and the network node (2). Mobile host according to any of claims 1-3, characterized in that the mobile host (1) is adapted to encrypt said initial connection between the mobile host (1) and the network node (2). Mobile host according to any of claims 1-4, characterized in that the mobile host (1) is provided with a plurality of authentication and authorization data for the provision of the network node (2) by utilizing said established initial connection between the mobile host (1). ) and the network node (2), wherein said plurality of authentication and authorization data is used by the mobile host (1) for ·· * • ♦ * * · * authentication and authorization in said plurality of access networks (7) in said heterogeneous • · | # " network system. 6. Mobile host according to any of claims 1-5, characterized in that the * ·· mobile host (1) is provided with means for collecting the results of the measurements. of a service level, where said service level measurements are measured between the access network transmitter portion with service level readiness and the mobile host's receiver part with • · · service level readiness. • · • · · • v • * * · *;: / 7. Mobile host according to any of claims 1 -6, characterized in that the • in ”* mobile host (1) is provided with means for selecting access networks (7) on the basis of • ♦ * * * ·. *. Scanned identifiers for the access networks (7), of the control host · ··· • and the measurement database (10) of the mobile host (1) stored the information about the service level measurements, the information stored on the control and measurement database (10) of the mobile host (1) (22) of service level contracts, of data obtained from the network node (2) or on the base of a combination of the aforementioned base parts of the information, and the said choice of access network (7) can be controlled by means of parameters stored in the control and measurement database (10) in the mobile host (1). * · • »· • tf ·· • · · ·· * · · · · · · · · · ··· ···» »·· • * · • · • · * · · · · ♦ · · · · · · · ··· • # ··· • · • · 9 • · · ··· * ··· • · · ··· • · • · ··· · · · · · · · · ···