RU2377728C2 - Management and administration of access to several networks - Google Patents

Abstract

FIELD: physics; communications.

SUBSTANCE: invention relates to wireless communication systems. Proposed invention relates to a mobile communication and method of registering in a network from a mobile communication device. A processor in the mobile device can be used for establishing a network connection with a server in the network. The mobile device can also have a transceiver which receives information from the server, related to the network connection. The processor can use the information, local measurements or both to determine whether to register in the network.

EFFECT: high quality of service.

28 cl, 3 dwg

Description

This patent application claims the priority of provisional patent application US serial number 60 / 589,897, registered July 20, 2004, and provisional patent application US serial number 60 / 675,337, registered April 26, 2005, which are included in this document link in its entirety.

FIELD OF THE INVENTION

The present invention, in General, relates to telecommunications and, in particular, to systems and methods for managing and managing access to multiple networks in a wireless communication system.

State of the art

The demand for wireless information services has led to the development of an ever-growing number of wireless networks. The CDMA2000 1x standard is just one example of a wireless network that provides global telephony and data services. The CDMA2000 1x standard is a wireless standard published by the Third Generation Network Partnership Project (3GPP2) utilizing Code Division Multiple Access (CDMA) technology. CDMA is a technology that allows multiple users to share a common communications environment using broadband processing. The competing wireless network commonly used in Europe is the Global System for Mobile Communications (GSM). Unlike the CDMA2000 1x standard, GSM uses narrowband time division multiple access (TDMA) to support wireless telephony and data services. Some other wireless networks include the General Packet Radio Service (GPRS) system, which supports high-speed data services with data rates suitable for e-mail and WAN browsing applications, and the universal mobile communications system (UMTS), which can deliver voice and broadband data for audio and video applications.

In general, these wireless networks can be considered as large-scale networks using cellular technology. Cellular communication technology is based on a topology in which the geographic coverage area is divided into cells. Within each of these cells, there is a fixed base transceiver station (BTS) that interacts with mobile users. A base station controller (BSC) is typically used in a geographic coverage area to control base transceiver stations (BTS) and route data to the appropriate gateways for various packet-switched and circuit-switched networks.

As demand for wireless data services continues to grow, mobile devices are evolving to support integrated voice, data and streaming environments, providing seamless network coverage between large-scale cellular networks and wireless local area networks (LANs). Wireless local area networks (LANs) typically provide telephony and data services in relatively small geographic areas using a standard protocol such as IEEE 802.11 standard, Bluetooth standard, etc. The existence of wireless local area networks (LANs) provides a unique opportunity to increase the volume of users in large-scale cellular network by expanding cellular communications to the unlicensed frequency spectrum using the wireless local area network (LAN) infrastructure.

Recently, various techniques have been used to enable mobile devices to interact with various wireless networks. However, before a mobile device moving over a large-scale cellular network switches to a wireless local area network (LAN), some parameters must be satisfied in order to ensure that the quality of service is not reduced to an unacceptable level.

SUMMARY OF THE INVENTION

One aspect of a mobile communication device is disclosed. The mobile communication device includes a processor configured to establish a network connection with a server on the network, and a transceiver configured to provide the processor with information received from the server, the information related to the network connection. The processor is configured to additionally determine, based on the information, whether to register on the network.

Another aspect of a mobile communication device is disclosed. A mobile communication device includes a processor configured to establish a network connection with a server on a network and measure at least one element of a plurality of forward, jitter, or packet loss packets in a network connection. The processor is further configured to determine whether to register on the network based on the at least one measurement.

One aspect of a method for interacting with a network from a mobile communication device is disclosed. The method comprises the steps of establishing a network connection with a server on the network, receiving information related to the network connection from the server, and determining based on the information whether to register on the network.

Another aspect of a method for interacting with a network from a mobile communication device is disclosed. The method comprises the steps of establishing a network connection with a server on the network, measuring at least one element of the set consisting of delay, jitter or loss of packets in the network connection in the forward direction, and determining whether to register on the network by based on said at least one dimension.

Another aspect of a mobile communication device is disclosed. The mobile communication device includes means for establishing a network connection with a server on the network, means for receiving information related to the network connection from the server, and means for determining, based on the information, whether to register on the network.

Another aspect of a mobile communication device is disclosed. A mobile communication device includes means for establishing a network connection with a server on the network, means for measuring at least one element of the set consisting of delay, jitter, or loss of packets in the forward direction of the network connection, and means for determining whether to register with networks based on said at least one dimension.

It is intended that other embodiments of the present invention become readily apparent to those skilled in the art from the following detailed description, which shows and describes only various embodiments of the invention by way of illustration. As will be understood, the invention is capable of various other embodiments, and several of its details may be changed in various other respects without departing from the spirit and scope of the present invention. Accordingly, the drawings and detailed description are to be regarded as illustrative in nature and not as restrictive.

Brief Description of the Drawings

Various aspects of a wireless communication system are illustrated by way of example, and not by way of limitation, in the accompanying drawings, in which:

Figure 1 is a schematic block diagram of an embodiment of a wireless communication system;

Figure 2 is a functional block diagram illustrating an example of a mobile device that can support both cellular and wireless local area network (LAN) communications; and

Figure 3 is a block diagram illustrating the operation of the selection algorithm in a mobile device for registration in the network.

Detailed description

The detailed description set forth below, together with the accompanying drawings, is intended to describe various embodiments of the invention and is not intended to represent the only embodiments in which the invention may be practiced. The detailed description includes specific details to provide a thorough understanding of the invention. However, it will be apparent to those skilled in the art that the invention may be practiced without these specific details. In some instances, well-known structures and components are shown in block diagram form in order to avoid obscuring the concepts of the invention.

In the following detailed description, methods for selecting a network in an environment with multiple networks will be described. Many techniques will be described in the context of a mobile communication device moving through a large-scale cellular network with one or more wireless local area networks (LANs) dispersed throughout the cellular coverage area. A mobile communication device can be any suitable device that can provide wireless telephony or data transfer, such as a cell phone designed to operate on a CDMA2000 1x network. A mobile communications device may be able to use any suitable protocol to gain access to a wireless local area network (LAN), including, as an example, an IEEE 802.11 network. Although these techniques can be described in the context of a cell phone that can interface with an IEEE 802.11 network, those skilled in the art will readily understand that these techniques can be extended to other mobile communication devices that can access multiple networks. For example, these techniques can be applied to a mobile communications device that can switch between a CDMA2000 1x network and a GSM network. Alternatively, these techniques can be applied to a mobile communications device that can access a separate network, such as an IEEE 802.11 telephone. An IEEE 802.11 telephone can be configured to connect to a wireless local area network (LAN) only if certain parameters indicate that the quality of service is acceptable. Accordingly, any reference to a cell phone that can interface with an IEEE 802.11 network, or any other specific embodiment, is intended only to illustrate various aspects of the present invention, with the understanding that these aspects have a wide range of applications.

1 is a schematic block diagram of an embodiment of a wireless communication system. Through a series of dashed lines, it is shown that the mobile device 102 moves through a large-scale cellular network 104. The cellular network 104 comprises a base station controller (BSC) 106 supporting a plurality of base transceiver stations (BTSs) distributed throughout the cellular coverage area. For ease of explanation, FIG. 1 shows a single base transceiver station (BTS) 108. A mobile communications center (MSC) 110 may be used to provide a gateway to a public switched telephone network 112 (PSTN). Although not shown in FIG. 1, cellular network 104 may use several base station controllers (BSCs), each of which supports any number of base transceiver stations (BTS), to expand the geographical reach of cellular network 104. When used throughout the cellular network 104 multiple base station controllers (BSCs), a mobile communications center (MSC) 110 may also be used to coordinate the relationship between base station controllers (BSCs).

Mobile device 102 is initially shown at location A in FIG. As the mobile device 102 moves through cellular network 104 from location A to location B, it falls within the coverage area of wireless local area network (LAN) 114. Wireless local area network (LAN) 114 may be an IEEE 802.11 network or any other suitable network. Wireless Local Area Network (LAN) 114 includes an access point 116 for a mobile device 102 for communicating with an IP network 118. Server 120 may be used to connect the IP network 118 to a mobile communications center (MSC) 110, which provides a gateway to a public switched telephone network 112 (PSTN).

When the mobile device 102 is initially turned on, it registers with either the cellular network 104 or the wireless local area network (LAN) 114. “Registration” refers to the process by which the mobile device 102 instructs the mobile communication center (MSC) 110 to route telephone network calls 112 public use (PSTN) over a specific network. The decision to register on a particular network may vary depending on the particular application and general design constraints. As an example, the mobile device 102 may be configured to register with a wireless local area network (LAN) 114 if the quality of service is acceptable. By routing all calls to the mobile device 102 through the wireless local area network (LAN) 114, expensive cellular bandwidth for other mobile users can be freed. The quality of service of the wireless local area network (LAN) 114 can be determined by the mobile device 102 based on local measurements and information from the server 120. If the quality of service of the wireless local area network (LAN) 114 cannot be maintained at an acceptable level, the mobile device 102 registers with the cellular networks 104. In mobile devices with no cellular capabilities, local measurements and information from server 120 can be used to determine if mobile device 102 should register with wireless locator the local area network (LAN) 114 or remain inactive until the quality of service becomes acceptable.

The registration process begins with the mobile device 102 attempting to access the wireless local area network (LAN) 114 when the power is first turned on. Mobile device 102 may use any suitable access procedure. As an example, mobile device 102 may use a passive access procedure in which mobile device 102 searches for a beacon from access point 116. The beacon is a periodic signal with synchronization information transmitted by the access point 116. Alternatively, the mobile device 102 may use an active access procedure in which the mobile device 102 transmits a test signal and awaits a response from the access point 116.

When the mobile device 102 cannot access the wireless local area network (LAN), which may be the case if the power is turned on at the mobile device 102 at location A, then the mobile device 102 attempts to access the cellular network 104. The mobile device 102 can access to the cellular network 104, receiving the experimental signal from the base transceiver station (BTS) 108. Once the mobile device 102 receives the experimental signal, a wireless connection can be established between them by means of state of the art. A wireless connection may be used by the mobile device 102 to register with the mobile communications center (MSC) 110.

As the mobile device 102 moves through cellular network 104 from location A to location B in the illustrated embodiment, it begins to detect a beacon from access point 116. Once the mobile device 102 detects a beacon, a wireless connection can be established between them using means known in the art. Then, the mobile device 102 obtains the IP address of the server 120. The mobile device 102 can use the domain name server (DNS) services to determine the IP address of the server. The domain name of the server 120 can be delivered to the mobile device 120 over the cellular network 104. Having an IP address, the mobile device 102 can establish a network connection with the server 120. The term “network connection” refers not only to the network layer connection between the mobile device 102 and the server 120 , but also to lower layer connections required to support a network connection, including physical layer connections. Once a network connection is established, information from the server 120 can be used in conjunction with local measurements to determine whether to renew its registration with the Mobile Communications Center (MSC) 110 so that future calls are routed through the wireless local area network (LAN) 114.

Figure 2 is a functional block diagram illustrating an example of a mobile device that can support both cellular and wireless local area network (LAN) communications. Mobile device 102 may include a cellular transceiver 202 and a wireless local area network (LAN) transceiver 204. In at least one embodiment of a mobile device 102, a cellular transceiver 202 can communicate with a CDMA2000 1x standard with a base transceiver station (BTS) (not shown), and a wireless local area network (LAN) transceiver 204 can communicate with an IEEE 802.11 standard with an access point (not shown). However, those skilled in the art will readily understand that the concepts described with respect to mobile device 102 can be extended to other cellular technologies or wireless local area network (LAN) technologies. Each transceiver 202, 204 is shown with a separate antenna 206, 207, respectively, but transceivers 202, 204 can share a single broadband antenna. Each antenna 206, 207 may include one or more radiating elements.

The mobile device 102 is also shown with a processor 208 connected to both the cellular transceiver 202 and the wireless local area network (LAN) transceiver 204, however, in alternative embodiments of the mobile device 102, separate processors for each transceiver may be used. The processor 208 may be implemented as hardware, firmware, software, or any combination thereof. By way of example, processor 208 may include a microprocessor (not shown). The microprocessor can be used to support software applications that, among other things, (1) control and manage access to the cellular network and wireless local area network (LAN) and (2) serve as the interface of the processor 208 with a keyboard 210, a display 212, and other user interfaces (not shown). The processor 208 may also include a digital signal processor (DSP) (not shown) with an integrated software layer that supports various signal processing functions, such as convolutional coding, modulation, and broadband processing. The Digital Signal Processor (DSP) can also serve as a vocoder to support telephony applications. The method of implementation of the processor 208 will depend on the particular application and design constraints imposed on the entire system. Those skilled in the art will understand the interchangeability of hardware configurations, firmware, and software under these circumstances and how best to implement the described functionality for each particular application.

The processor 208 may be configured to execute a selection algorithm. A selection algorithm may be used to determine if mobile device 102 should register with a cellular network or a wireless local area network (LAN). The selection algorithm may be implemented as one or more software applications supported by the microprocessor-based architecture described previously. Alternatively, the selection algorithm may be a separate module from processor 208 implemented in hardware, software, firmware, or any combination thereof. Depending on the specific constraints of the project, the selection algorithm may be embedded in any object in the mobile device 102 or distributed over several objects in the mobile device 102.

The criteria used by the selection algorithm may vary depending on the particular implementation. As described above, the criteria may include local measurements made by the mobile device and information provided by the server. 1, these local measurements may include various quality metrics that show the quality of the network connection. By way of example, the mobile device 102 may measure the transmission signal strength from the access point 116. In telephony applications, measurements of latency, jitter, and packet loss can be used as additional quality metrics related to the forward network connection. “Forward” refers to transmissions over a network connection from server 120 to mobile device 102, and “reverse direction” refers to transmissions over a network connection from mobile device 102 to server 120. Information provided by server 120 may include data that indicate the load on the access point 116, historical information regarding the performance of the access point 116, quality indicators such as delay, jitter, and packet loss in the opposite direction, or any other information that relies on tsya on the quality of the network connection.

1 and 2, the signal strength from the access point can be measured in the mobile device 102 using the received signal strength indicator (RSSI) block 216. Received Signal Strength Indicator (RSSI) is most likely an existing signal that is returned to the wireless local area network (LAN) transceiver 202 for automatic gain control, and therefore can be provided to the processor 208 without increasing the complexity of the circuitry of the mobile device 102. Alternatively, the quality of the wireless connection may be identified by a lighthouse. Since the beacon is a broadband signal that is known in advance, an exact copy of the beacon signal can be stored in memory (not shown) on the mobile device 102. A demodulated beacon signal can be used together with an exact copy of the beacon signal stored in memory to estimate the energy transmitted a beacon signal by means known in the art.

The selection algorithm can also be used to calculate various quality metrics related to the forward network connection. As stated earlier, one of these quality metrics is forward latency in a network connection. In telephony applications, excessive latency can result in poor quality due to unwanted echo or speech overlay. The selection algorithm may be configured to measure the delay by any suitable means. In at least one embodiment of a wireless communication system, date and time stamps in beacons and control signals transmitted from server 120 may be used to measure latency in a network connection. In particular, when forward direction transmission is received by mobile device 102, the time stamp may be retrieved in the processor 208 and compared with the local time of the internal clock (not shown) in the mobile device 102. The result, which is a delay in the network connection in the forward direction, can be saved Anen in memory (not shown). The selection algorithm may determine whether to register on the wireless local area network (LAN) 114 using the delay value stored in memory for the most recent transmission, or, alternatively, the average delay from several delay values.

Using timestamps to measure latency in a network connection requires that the local clock be synchronized with server 120. A remote time source (not shown) can be used to synchronize mobile device 102 with server 120. The remote time source can be one of the many servers on the IP network 118 that are synchronized with Coordinated Universal Time (UTC) via a radio, satellite, modem, or other means. The remote time source can be used to provide time information for updating or synchronizing the time of the internal clock in the mobile device 102. This can be achieved using a program known as the network time service protocol (NTP). Network Time Service Protocol (NTP) is a standard Internet protocol for clock synchronization with some reference time. The Network Time Service Protocol (NTP) may be executed on the processor 208 or elsewhere on the mobile device 102.

Delay problems in telephony applications can also be complicated by the need to remove jitter. Jitter is a change in packet delay due to network congestion, clock bias, or routing changes. Eliminating jitter requires buffering inbound packets so that all packets can play continuously in the correct order. The packet buffering process adds extra delay. Thus, the algorithm can also be configured to measure jitter in a network connection in the forward direction as an additional measure of quality. In the case of an adaptive jitter buffer that adapts to changes in network delay, the delay measured by the selection algorithm may include network jitter depending on where the measurement path is taken. In the case of a fixed wobble buffer that adds a fixed delay to the packet, the selection algorithm may decide to measure network jitter from changes in the delay values stored in memory. The selection algorithm may determine whether to register with the wireless local area network (LAN) 114 using a change in the worst-case delay values, an average change in the delay values, or any other suitable computing technique.

Lost packets can be especially problematic in telephony applications. Since IP networks do not guarantee service, they will usually exhibit a high number of lost packet cases. In IP networks, voice packets are processed in the same way as data. As a result, voice packets will be lost equally with data packets when the IP protocol network is heavily congested. However, unlike data packets, voice packets cannot simply be retransmitted at a later time. A selection algorithm may also be used to calculate a quality score related to lost packets by any suitable means. As an example, a beacon and control signals transmitted from server 120 may also include sequence numbers in addition to date and time stamps. When the forward direction transmission is received by the mobile device 102, the sequence numbers can be extracted in the processor 208 and used by the selection algorithm. A sequence-based selection algorithm can determine which packets were lost.

In addition to the quality indicators described above, the selection algorithm may use information from the server 120 to determine whether to register on the wireless local area network (LAN) 114. As described previously, the information may relate to the load on the access point 116. Although the wireless local area network (LAN) ) 114 uses a wide range to support communications, overhead can limit the number of mobile users that can be supported by access point 116. In addition, the presence of other mobile users in over a wireless local area network (LAN) 114 may put an additional burden on the access point 116. Server 120 may be configured to maintain a database that includes each mobile user that has registered with the wireless local area network (LAN) 114 through the access point 116 When the new mobile device 102 establishes a network connection, server 120 may consult a database to determine how many mobile users are currently logged into the wireless local area network (LAN). 114, use the access point 116. This information can be provided to the selection algorithm in the mobile device 102 over a network connection. The selection algorithm may use this information to determine whether to register on the wireless local area network (LAN) 114.

The information provided by the server 120 to the mobile device 102 may also include historical information about the access point 116. As an example, the server 120 may track the number of calls lost by the access point 116 by means known in the art. This information can be stored in the server database and transmitted to the mobile device 102 as soon as the network connection is established. The selection algorithm in the mobile device 102 may use this information to help estimate the load on the access point 116. If there are a large number of calls lost by the access point 116, the selection algorithm may decide to register on the wireless local area network (LAN) 114 only if the access point not heavily loaded. Conversely, if the number of cases of lost calls is small, the selection algorithm may take a more aggressive approach and decide to register with the wireless local area network (LAN) 114, even if the access point 116 is heavily loaded.

Server 120 can also be used to calculate various quality metrics related to the network connection in the reverse direction. These quality indicators may include delay, jitter, lost packets, and any other parameters that rely on the quality of the network connection. Server 120 may calculate these quality measures in the same manner as described above with respect to the selection algorithm, or by any other suitable means. In cases where the delay or jitter is calculated using date and time stamps in the control signals transmitted from the mobile device 102 via a network connection, the network protocol Time Service (NTP) can be used by the server 120 to synchronize its internal clock. The sequence numbers inserted in the control signals of the mobile device 102 can also be used by the server 120 to identify lost packets. These quality indicators can be used by the selection algorithm in the mobile device 102. These quality indicators can be used together with the quality indicators measured by the selection algorithm to provide a complete picture of the network connection in both forward and reverse directions.

3 is a block diagram illustrating the operation of a selection algorithm in a mobile device. At step 302, the selection algorithm is activated as soon as a network connection is established between the mobile device and the server. The selection algorithm remains inactive until it receives information from the server in step 304. In this example, the information indicates the load on the access point. At step 306, the selection algorithm determines whether the load on the access point exceeds a threshold value. If the selection algorithm determines that the load on the access point exceeds a threshold value, then it interrupts the registration procedures in the wireless local area network (LAN) at step 308. In the case where the mobile device can perform operations of both the cellular network and the wireless local area network (LAN) ), the mobile device registers on the cellular network. In the case where the mobile device can only perform operations on a wireless local area network (LAN), the mobile device remains inactive until the load on the access point is reduced. The threshold value may be generated in the mobile device or, alternatively, provided to the mobile device from the server via a network connection. In any case, the threshold value may be customizable based on historical information stored in the server database.

Assuming that the mobile device determines that the load on the access point does not exceed a threshold value, the registration procedure continues. At step 310, the selection algorithm measures various quality metrics related to the network connection in the forward direction. At step 312, the selection algorithm also receives information from the server. Information from the server may include various quality indicators related to the network connection in the opposite direction. At step 314, quality indicators are evaluated by a selection algorithm. If the quality indicators indicate that the quality of service is unacceptable, then the selection algorithm ends the registration procedures at step 316. The operation of the mobile device after the registration procedures are completed, again depends on the type of device used. On the contrary, if the quality indicators indicate that the quality of service is acceptable, then the selection algorithm ends the registration process in a wireless local area network (LAN) at step 318.

The various illustrative logical blocks, modules, circuits, elements, and / or components described in relation to the embodiments disclosed herein may be implemented or implemented using a general-purpose processor, digital signal processor (DSP), application-specific integrated circuit (ASIC), programmable valve matrix (FPGA) or other programmable logic component, logic with a low degree of integration or transistor logic, individual hardware components, or any combination thereof performed with the ability to perform the functions described here. A general purpose processor may be a microprocessor, but in the alternative, the processor may be any conventional processor, controller, microcontroller, or state machine. A processor may also be implemented as a combination of computing components, for example, a combination of a digital signal processor (DSP) and a microprocessor, a plurality of microprocessors, one or more microprocessors together with a digital signal processor (DSP) core, or any other such configuration.

The methods or algorithms described in relation to the embodiments disclosed herein may be implemented directly in hardware, in a software module executed by a processor, or in a combination thereof. The program module may reside in random access memory (RAM; RAM), flash memory, read-only memory (ROM), erasable programmable read-only memory (EPROM; EPROM), electrically erasable programmable read-only memory (EEPROM; EEPROM) , registers, hard disk, removable disk, read-only compact disc (CD-ROM) or storage medium of any other kind known in the art. The storage medium may be connected to the processor so that the processor can read information from the storage medium and write information to the storage medium. Alternatively, the storage medium may be integrated in the processor.

The preceding description is given to enable any person skilled in the art to put into practice the various embodiments described herein. Various modifications to these embodiments will be readily apparent to those skilled in the art, and the generic principles defined herein may be applied to other embodiments. Thus, it is understood that the claims are not limited to the embodiments shown here, but should correspond to the full scope consistent with the claims, in which the mention of the element in the singular does not imply the meaning of "one and only one", unless specifically stated, and the value is one or more. All structural and functional equivalents of the elements of the various embodiments described in this disclosure that are known or later became known to those skilled in the art are expressly incorporated herein by reference and are intended to be embraced by the claims. Furthermore, nothing disclosed herein is intended to become public domain, irrespective of the fact that such disclosure is expressly set forth in the claims. No feature of the claims should be construed in accordance with the sixth paragraph of Section 112 of Section 35 of the United States Code unless explicitly stated using the phrase “means for” or, in the case of a claim, describing the method, the feature is made using the phrase “step for".

Claims (28)

1. A mobile communication device operable to communicate in a cellular network and a wireless local area network (LAN), comprising
a processor configured to establish a cellular connection with a server on a cellular network, the processor being configured to establish a network connection with a server on a LAN;
a cellular transceiver configured to communicate with the cellular network and provide the processor with information received from a server on the cellular network; and a LAN transceiver configured to communicate with the LAN and provide the processor with information received from a server on the LAN; wherein said information relates to a network connection and a cellular connection; moreover, the processor is configured to register on a LAN and / or a cellular network based on the above information, the processor is further configured to use a LAN to support cellular services if the processor determines that it is registered on the LAN. 2. The mobile communication device according to claim 1, in which the cellular transceiver is configured to establish a wireless connection with the access point to support the cellular connection, the information received by the cellular transceiver from the server including the load on the access point. 3. The mobile communication device according to claim 2, in which the information received by the cellular transceiver from the server includes historical information related to the access point. 4. The mobile communications device of claim 1, wherein the information received by the LAN by the transceiver from a server on the LAN includes a quality metric related to the network connection. 5. The mobile communication device according to claim 4, in which the quality indicator relates to the delay, jitter or loss of packets in a network connection in the opposite direction. 6. The mobile communication device according to claim 1, in which the processor is made with the additional ability to measure at least one element from the set consisting of delay, jitter, or packet loss in the network connection in the forward direction, and determine whether to register in LAN, both on the basis of information received from the server, and on the basis of the at least one dimension. 7. The mobile communication device according to claim 1, in which the cellular transceiver is made with the additional ability to establish a wireless connection with the access point to the cellular network, the processor is made with the additional ability to measure the signal intensity of the wireless transmissions from the access point and determine whether to register on the network LAN, both based on information received from the server, and based on the measured signal intensity. 8. The mobile communications device of claim 1, wherein the LAN transceiver is an IEEE 802.11 standard transceiver. 9. A mobile communication device operable to communicate in a cellular network and a wireless local area network (LAN), comprising
a processor configured to establish a network connection with a server on a LAN, the processor being further configured to establish a cellular connection with a server on a cellular network and measure at least one element from a set consisting of delay, jitter, or packet loss on the network connection in the forward direction; a cellular transceiver configured to communicate with a cellular network; A LAN transceiver configured to communicate with a LAN; moreover, the processor is configured to register on a LAN and / or a cellular network based on the measurement, the processor is further configured to use a LAN to support cellular services if the processor determines that it is registered on the LAN. 10. The mobile communications device of claim 9, wherein the LAN transceiver is further configured to provide the processor with information received from a server on the LAN, the information being related to the network connection, the processor being further configured to determine whether to register on the network LAN, both on the basis of said at least one dimension and on the basis of information. 11. The mobile communication device of claim 10, in which the cellular transceiver is configured to establish a wireless connection with the access point to support the cellular connection, and the information received by the cellular transceiver from the server includes a load on the access point. 12. The mobile communications device of claim 11, wherein the information received by the cellular transceiver from the server includes accumulated information related to the access point. 13. The mobile communications device of claim 11, wherein the information received by the LAN transceiver from the server includes a quality metric related to the network connection. 14. The mobile communication device according to item 13, in which the quality indicator relates to delay, jitter or packet loss in a network connection in the opposite direction. 15. The mobile communication device according to claim 9, in which the cellular transceiver is made with the additional ability to establish a wireless connection with an access point to the cellular network, the processor is made with the additional ability to measure the signal intensity of the wireless transmissions from the access point and determine whether to register on the network LAN, both on the basis of the at least one measurement and on the basis of the measured signal intensity. 16. The mobile communication device according to claim 9, in which the LAN transceiver is an IEEE 802.11 standard transceiver. 17. A method of interacting with a cellular network and a wireless local area network (LAN) network from a mobile communication device operable to communicate in a cellular network and a LAN network, comprising the steps of: establishing, by means of a processor, a network connection to a server on a LAN or a cellular connection to a server on the cellular network;
communicate via a LAN transceiver with a LAN network and provide information from a server to a processor or communicate through a cellular transceiver with a cellular network and provide information from a server to a processor; wherein said information relates to a network connection and a cellular connection; are registered by a processor on a LAN or a cellular network based on said information; and supporting, by the processor, cellular services over the LAN if the processor determines that it is registered on the LAN. 18. The method of claim 17, further comprising establishing a wireless connection with the access point via the cellular transceiver to support the cellular connection, the information received by the processor from the server including a load on the access point. 19. The method according to 17, in which the received information includes a quality indicator related to a network connection. 20. The method according to 17, further comprising measuring at least one element of the set consisting of delay, jitter, or packet loss in the forward direction of the network connection, the determination of whether to register on the LAN, based both on information received from the server, and on said at least one dimension. 21. The method according to 17, in which the LAN is an IEEE 802.11 network. 22. A method of interacting with a cellular network and a wireless local area network (LAN) network from a mobile communication device operable to communicate in a cellular network and a LAN network, comprising the steps of: establishing, by means of a processor, a network connection to a server on a LAN; measuring by means of the processor at least one element of the set consisting of delay, jitter, or packet loss in the forward direction of the network connection; registered by the processor in a LAN or a cellular network based on said measurement; support cellular services over the LAN if the processor determines that it is registered on the LAN. 23. The method according to item 22, also containing a stage on which information related to the network connection is received from the server, the determination of whether to register on the LAN is based on both said at least one dimension and information . 24. The method according to item 23, also containing a stage on which to establish through the processor a wireless connection with an access point to a cellular network, and the received information includes the load on the access point. 25. The method according to item 23, in which the information received by the processor from the server includes a quality score related to the network connection. 26. The method of claim 22, wherein the LAN is an IEEE 802.11 network. 27. A mobile communication device operable to communicate in a cellular network and a wireless local area network (LAN), comprising
means for establishing a connection to a server on a LAN or a cellular network; means for communicating with the cellular network and providing information received from the server for means for establishing a connection;
means for communicating with the LAN and providing information received from the server for means for establishing a connection; wherein said information relates to a network connection and a cellular connection; moreover, the means for establishing a connection is made with the additional possibility of registering in the LAN and / or the cellular network based on the above information, the means for establishing the connection is made with the additional possibility of using the LAN to support cellular services, if the means for establishing the connection determines that it registered on the LAN. 28. A mobile communication device operable to communicate in a cellular network and a wireless local area network (LAN), comprising means for establishing a connection with a server in a cellular network or in a LAN, and measuring at least one element of a plurality of delays, jitter, or packet loss in the network connection in the forward direction; means for communicating with a cellular network; means for communicating with a LAN; moreover, the means for establishing a connection is made with the additional possibility to register in the LAN and / or cellular network based on the said measurement; moreover, the means for establishing a connection is made with the additional possibility of using a LAN to support cellular services, if the means for establishing a connection determines that it is registered in the LAN.

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