Patent Application
20080153484
The present invention relates generally to telecommunications systems, and in particular to methods and systems for improving the Quality of Service (QoS) in roaming applications associated therewith.
At its inception cellular phone technology was designed and used for voice communications only. As the consumer electronics industry continued to mature, and the capabilities of processors increased, more devices became available for public use that allowed the transfer of data between devices and more applications became available that operated based on their transferred data. Of particular note are the Internet and local area networks (LANs). These two innovations allowed multiple users and multiple devices to communicate and exchange data between different devices and device types. With the advent of these devices and capabilities, users (both business and residential) found the need to transmit data, as well as voice, from mobile locations.
In addition to lower costs and more coverage, this has helped drive the next generation of cellular devices to have the ability to transmit and receive data. For example, one of the second generation implementations of cellular phone technology was the Global System for Mobile Communications (GSM). GSM was originally a digital voice technology. An ability to transmit and receive data was grafted on to this system in what could be called generation 2.5 through the use of General Packet Radio Services (GPRS) in combination with the GSM system. GPRS allows mobile phones that use the GSM system to transmit internet protocol (IP) packets. The third generation system that inherits parts of the GSM system is called the Universal Mobile Telecommunications System (UMTS). The UMTS has higher data transmission rates than GSM/GPRS and allows for new and improved options for a mobile user, such as mobile video conferencing.
Among other features, UMTS networks offer improved services to users while they are outside of their normal geographic zones. The ability to access services while one is outside of their home network is typically known as roaming. To access data services while a user is roaming, that user's signaling is first forwarded to a Gateway GPRS Support Node (GGSN) router located in the user's home network so that user can access the particular services to which she or he has subscribed. Then, the user's signaling is forwarded to the desired destination. The GGSN router that manages routing and forwarding for the mobile user is identified by a user's mobile equipment by an Access Point Name (APN).
APNs are a part of the activate Packet Data Protocol (PDP) context request message which is sent by a user's mobile device. This message is sent to a Serving GPRS Support Node (SGSN). An APN contains the name of an access point for GPRS and typically includes an IP network to which a mobile device can be connected. The two principal functions that an APN fulfills are as follows: (1) an APN indicates without ambiguity the Packet Data Network (PDN) which the mobile user wishes to reach; and (2) the APN identifies a service which the mobile user wishes to access. A PDN is a network providing a data service, an example of which is the Internet. Each Public Land Mobile Network (PLMN) can be connected to several PDNs through one or more GGSNs. With the APN, the access point to a PDN in a particular PLMN can be specified by using a name that is compliant to the Domain Name System (DNS) naming system for a given GGSN.
More specifically, an APN consists of up to 100 octets, wherein an octet is the equivalent of an 8-bit byte, and is made up of two parts. The two parts of an APN are the Network Identifier, which is mandatory, and the APN Operator Identifier which is optional. The APN Network Identifier describes the external network to which the GGSN is connected and, optionally, the service that is required by the mobile terminal. The APN Network Identifier has a maximum length of 63 bytes (or 63 ASCII characters). Moreover, in order to guarantee the uniqueness of the network identifiers in a PLMN, all network identifiers consisting of more than one label correspond to an Internet domain name allocated by the PLMN for the purpose of identifying an organization that has reserved this label.
Each operator has a default APN Operator Identifier which is composed of three fields. The first and second fields together uniquely represent a PLMN network. The third field is required to be “gprs”. More specifically, the first field contains three digits and represents the mobile country code (MCC). The second field, which also contains three digits, is called the mobile network code (MNC) and identifies the mobile home PLMN network. Thus, an example of the standard format of an APN Operator Identifier is “mcc.345.mnc012.gprs” for an MCC=345 and an MNC=12. This exemplary APN Operator Identifier is used while roaming inter-PLMN and when the APN translation is made into the Internet Protocol (IP) address of a GGSN from the home PLMN.
Additionally, an APN is usually geographically dependent, such that the APN often refers to a GGSN located in the mobile user's home network and not in the network within which the mobile user is roaming. This geographical anchoring can cause delays due to the travel length. For example, suppose that a mobile user has his or her local service based in the United States and is on a trip to Sweden. The mobile user makes a local phone call, but due to his or her mobile unit being local to the United States, the call is routed to the home base (GGSN) in the United States first before being forwarded to the local number in Sweden. This delay can be increased depending upon, for example, the type/size of the data being transmitted. Additionally problems can be encountered because a user's home address/source address is different from the roaming address, which can cause packets to be dropped due to security functions. As more and more users become members of the mobile network, and some of these users travel farther and farther away from their home address, it is expected that these problems will increasingly (and negatively) affect the user's quality of service (QoS).
Accordingly the present invention addresses the need for improving the QoS in mobile networks.
According to an exemplary embodiment, a telecommunication node includes a processor for receiving a message which requests a data service, wherein the message contains a service identification number which is used by the telecommunication node to determine a Gateway GPRS Support Node (GGSN) to support the data service.
According to another exemplary embodiment, a telecommunication method includes a step of receiving a message which requests a data service, wherein the message contains a service identification number which is used by a telecommunication node to determine a Gateway GPRS Support Node (GGSN) to support the data service.
According to a further exemplary embodiment, a mobile device includes a transceiver for transmitting a message which requests a data service, and wherein the message contains a service identification number which is usable to determine a Gateway GPRS Support Node (GGSN) to support the data service.
According to still another exemplary embodiment, a telecommunication method includes a step of transmitting a message which requests a data service, and wherein the message contains a service identification number which is usable to determine a Gateway GPRS Support Node (GGSN) to support the data service.
In yet another exemplary embodiment, a telecommunications node includes a processor for receiving router advertisement (RA) messages and for updating a Gateway GPRS Support Node (GGSN) list which is used to assign a GGSN to locally support a request for data service, wherein the processor invokes a home GGSN IP address discovery mechanism when the request is unable to be locally supported.
According to another exemplary embodiment, a telecommunications method includes the steps of receiving router advertisement (RA) messages, updating a Gateway GPRS Support Node (GGSN) list using the RA messages, assigning a GGSN to locally support a request for data service, and invoking, if the request cannot be supported locally, a home GGSN IP address discovery mechanism.
The accompanying drawings illustrate exemplary embodiments of the present invention, wherein:
a) depicts an exemplary Universal Mobile Telecommunications System (UMTS) including two PLMNs;
b) shows a portion of the system of
c) depicts an exemplary user equipment (e.g., mobile device) operable within the system of
d) shows an exemplary telecommunications node (e.g., a GGSN/SGSN) operable within the system of
The following detailed description of the exemplary embodiments refers to the accompanying drawings. The same reference numbers in different drawings identify the same or similar elements. Also, the following detailed description does not limit the invention. Instead, the scope of the invention is defined by the appended claims.
In order to provide some context for this discussion, an exemplary aggregated mobile system in which the present invention can be implemented will first be described with respect to
In this exemplary embodiment, the Universal Mobile Telecommunications System (UMTS) network depicted in
c) illustrates an exemplary UE in which exemplary embodiments can be implemented. Therein, the UE 102 includes a processor 120 connected to a transceiver 122. The transceiver 122 is, in turn, connected to an air interface via an antenna 124. It will be appreciated that UEs 102 will typically also include other elements, e.g., a display and memory devices. Similarly, telecommunication nodes, such as the GGSNs and SGSNs, can include processor(s) 130 and memory devices 132 as shown in
According to an exemplary embodiment of the present invention, in order to improve QoS in a UMTS system the Access Point Name (APN) described in the background is replaced by a service identification number (ServiceID). This Service ID, in conjunction with other features described below, fulfills the functions of an APN. More specifically, the ServiceID is a mechanism for indicating the Packet Data Network (PDN) which a mobile user wishes to reach and can, alternatively, identify a class of service which the user desires to use.
According to this exemplary embodiment, the ServiceID is a number, and has a format using five bytes as shown in Table 1.
The exemplary Service ID number of Table 1 can be described in two parts or fields. The first part is the function field and the second part is the Autonomous System Number (ASN) or service class field. In this example, the first byte constitutes the function field which is used to discriminate the function filled by the ServiceID in a particular instance, e.g., such as identification of a desired PDN or identification of a desired service. For example, the function field can take one of the following values according to this exemplary embodiment:
0 (Ob00000000): this value corresponds to a ServiceID wild card;
1 (Ob000000001): this value shows that this ServiceID indicates a PDN; and
3 (Ob000000011): this value shows that this ServiceID indicates a service.
For this exemplary embodiment, these are the only values that the function field can take. Thus, for this embodiment, if the function field contains values other than those defined, the ServiceID will be regarded as invalid or erroneous. However, it is to be understood that, as other options become available in the future, these field values could be modified as desired. The function field may have more, fewer or different values according to other exemplary embodiments.
Turning now to the second field in the ServiceID (ASN or service class), when the function field has the value 0, the number represented by the last four bytes will be 0. A function field containing the value 1 indicates a desired PDN, which is a network providing a data service. Thus, a ServiceID with a function field value of 1 describes the access point to a PDN independently of the PLMN. More specifically, when the function field has the value 1, the last four bytes of the ServiceID represent an ASN of 32 bits indicating a given PDN. The ASN is a number that makes it possible to uniquely identify each Autonomous System (AS). An AS is a group of Internet Protocol (IP) networks managed by one or more operators sharing only one routing policy. The ASNs are assigned by the Internet Assigned Number Authority (IANA).
When the Function field of a ServiceID has a value of 3, then the second field of the ServiceID is used to describe one of a number of different service classes. These service classes can be broken down into, for example, four QoS classes based upon the degree of sensitivity to potential traffic delay. When the ServiceID indicates a service, the last four bytes of the ServiceID will be able to take four values exactly corresponding to the following four UMTS service classes, according to this exemplary embodiment:
1.0.0.0 (0b00000001.00000000.00000000.00000000): this value corresponds to the class “conversational”;
3.0.0.0 (0b00000011.00000000.00000000.00000000): this value corresponds to the class “streaming”;
7.0.0.0 (0b00000111.00000000.00000000.00000000): this value corresponds to the class “interactive”; and
15.0.0.0 (0b00001111.00000000.00000000.00000000): this value corresponds to the class “background”.
To better understand how the ServiceIDs described above are used by exemplary embodiments of the present invention, e.g., both in the network and in the user equipment, the following detailed examples illustrate some usage cases wherein a roaming user accesses the network using the ServiceID. More specifically, three exemplary scenarios according to the present invention are described below for accessing a mobile network using a ServiceID according to these exemplary embodiments. These three scenarios can generally be described as follows: (1) the case wherein a roaming user's communications are managed by a visited GGSN; (2) the case wherein a roaming user's communications are managed by a home GGSN, e.g., due to refused permission from the visited GGSN; and (3) the case where a roaming user's communications are managed by a home GGSN due to the visiting networks inability to handle the request.
In the first scenario, a roaming user's communications are managed by a visited GGSN (VGGSN) when a user is in a visited PLMN (VPLMN) as shown in
Therein, at step 300, each GGSN 110 within a particular PLMN periodically broadcasts a message to the various SGSNs 108, referred to herein as a router advertisement (RA) message, within the same PLMN. This router advertisement message informs the SGSNs 108 of the identities of the available GGSNs 110, as well as the services which each GGSN 110 is able to provide to users. According to one exemplary embodiment, the router advertisement message can be implemented in a manner similar to the neighbor discovery procedure described in Mobile IP version 6 (MIPv6) protocol as described, for example, in the standards document RFC 2461 “Neighbor Discovery for IPv6”, 1998, the disclosure of which is incorporated here by reference. As the SGSNs 108 receive the router advertisement messages, they will use them to update their locally stored GGSN lists to include, among other things, each GGSN's IP address and the services that it supports at step 310.
In order to support the functionality associated with the GGSN list construction mechanism illustrated in
Additionally, the option field illustrated above in the RA message of Table 2 can be defined in a manner so as to convey relevant information about the GGSN which is broadcasting the messages for purposes of building the GGSN list, e.g., including specific information on specific router functionality. The format of this option is presented in Table 3.
The specific fields used in the GGSN Information option format according to this exemplary embodiment and as shown in Table 3 will now be described. Therein, the Type field is Neighbor Discovery option described in the above-incorporated by reference document. The Length field contains, e.g., an unsigned 8-bit integer indicating the length of the option. The GGSN Preference field contains, e.g., an unsigned 16-bit integer indicating the preferences of the GGSN. For this latter field, a high value indicates a high availability and can be used by the receiving SGSNs to order the GGSN list created in
The GGSN Lifetime field contains, e.g., an unsigned 16-bit integer indicating the lifetime of the GGSN in seconds. By default, this field takes the value of the lifetime of the router as specified in the principal body of a RA message. A value of zero is not preferred. The GGSN Lifetime field applies, according to this exemplary embodiment, only to the functionality of the router as a GGSN and not to the information in the other fields or options of the RA message. The ServiceIDs field is a list of ServiceIDs relating to the service classes or ASNs which the GGSN transmitting this RA message is able to provide. ServiceIDs can be placed contiguously within the ServiceID field of the options portion of an RA and parsed by the receiving SGSNs based upon a known length of, e.g., 5 bytes each.
Having described an exemplary GGSN list construction method which can be performed as step 202, and returning to the scenario of
Therein, at step 400, a GGSN selection mode which is operative to process this particular GGSN selection is determined. Various GGSN selection modes may be provided for depending upon the particular implementation of these exemplary embodiments. According to one exemplary embodiment, there are three GGSN selection modes from which a selection can be made at step 400: (1) ChosenByMN (chosen by the mobile network or user equipment) whereby the ServiceID is the ServiceID in the Activate PDP Context Request message; (2) ChosenBySGSN whereby the ServiceID is the default ServiceID associated with the known PDP type; and (3) Subscribed whereby ServiceID is extracted from the PDP context. The selection of a particular mode can be made by the network based upon parameters in the Activate PDP context request message and/or records in the Home Location Register (HLR) associated with the mobile user that transmitted the request message. Regardless, it will be appreciated that the GGSN selection mechanism of step 400 is a manner of selecting the ServiceID (i.e., either that transmitted by the mobile user or another) which will, in turn, be used to select a particular GGSN to provide the requested service.
Next, at step 410, it is determined which PLMN, i.e., the visited PLMN or home PLMN, will provide the data service identified by the ServiceID. In the exemplary scenario of
Returning to
Next, a Radio Access Bearer Setup procedure is undertaken in step 214. Step 214 can involve a QoS modification. If the QoS parameters were modified in step 214, the VSGSN and the VGGSN exchange update PDP context request and update PDP context response messages in order to modify these QoS parameters in the PDP context in steps 216 and 218, respectively. The VSGSN then sends an activate PDP context accept message to the MN (or user equipment) to conclude the procedure in step 220.
Thereafter, the VSGSN checks the user's subscription records to establish the validity of the request. Once the validity of the mobile user's request is established, the VSGSN applies the GGSN selection mechanism (illustrated in
In this scenario, since permission is refused by the system to use a local GGSN to provide service, the VSGSN needs to obtain a home GGSN's IP address associated with this mobile user. The GGSN list constructed at step 202 provides a list of local GGSNs and their attributes. However, the list of GGSNs in operation in another PLMN is inaccessible to SGSNs. Additionally, since the ServiceID provided by the mobile user in the Activate PDP Context Request is a number rather than a DNS address, the ServiceID does not provide a direct mechanism for accessing an HSGSN. Accordingly, these exemplary embodiments also provide a home GGSN IP addresses discovery mechanism to deal with those situations, such as that illustrated in
According to an exemplary embodiment, a home GGSN IP address discovery procedure 508 is carried out in the form of an exchange of messages between the SGSN of the visited PLMN (VSGSN) and an SGSN of the home PLMN (HSGSN) of the mobile user. The message 508a sent by the VSGSN for the purposes of this address discovery contains the ServiceID of the service which the GGSN must provide and is addressed to an address that makes it possible to join all the SGSNs of the Home PLMN. According to an exemplary embodiment, the message form can be similar to the Router Solicitation message used in above-incorporated by reference Neighbor Discovery protocol but modified for use with the ServiceID. This message 508a is referred to herein as the Internet Control Message Protocol (ICMP) Home GGSN Address Discovery Request. The ICMP Home GGSN Address Discovery Request format is presented in Table 4.
In Table 4, according to this exemplary embodiment, the Type field value is set to 154 in order to differentiate this ICMP message from other ICMP messages. The Code field is set to 0. The Checksum field is set to ICMP checksum. The Identifier field uses an identifier which allows the system to pair an ICMP Home GGSN Address Discovery Request message with the corresponding ICMP Home GGSN Address Discovery Response message. The Reserved field is reserved for future use, but initially set to 0. The ServiceID field displays the ServiceID of the service which is to be provided by the GGSN which is being identified within the home PLMN by this discovery mechanism.
The ICMP Home GGSN Address Discovery Request Message is sent to the roaming user's home SGSN unicast address by the SGSN of the visited network. The SGSN which receives this ICMP Home GGSN Address Discovery Request message carries out a search in its own GGSN list using the ServiceID contained in the message at step 508b. The SGSN then responds with an ICMP Home GGSN Address Discovery Response message 508c. Assuming a successful search, the ICMP Home GGSN Address Discovery Response message 508c contains a code indicating success as well as the GGSN IP address found. Otherwise, the message 508c contains a code indicating failure and the cause of failure. The ICMP Home GGSN Address Discovery Response message 508c is used by the SGSN of the roaming user's home network to answer the SGSN of the visited network which initiated the Home GGSN IP address discovery mechanism. An exemplary format for message 508c is presented in Table 5.
In Table 5, the Type field is set to 155 in order to differentiate this ICMP message from other ICMP messages. The Code field indicates whether the search in the GGSN list was successful or not. According to this exemplary embodiment, a value between 0 and 127 indicates a success, e.g., when the Home GGSN Address field contains the desired GGSN's IP address. If a failure in the search occurs, the value of the code lies between 128 and 255, which indicates that there was an error in the Home GGSN Address field. The Checksum field indicates an ICMP checksum. The Identifier field contains an identifier coming from ICMP Home GGSN Address Discovery Request message that allows the recipient to correlate the response with the earlier request in message 508a. The Reserved field is reserved for future use and is initially set to 0. The Home GGSN Address field contains the GGSN's IP address which was located by the GGSN list search or the cause of the error which resulted in a search failure.
If the ICMP Home GGSN address discovery response message 508c contains the HGGSN's IP address the process continues, otherwise the PDP context activation procedure is terminated. In step 510, the VSGSN sends a create PDP context request message to the HGGSN whose IP address was obtained in step 508. The HGGSN creates a new entry in its table of PDP contexts which will allow it to route the user's packets between the VSGSN and the network PDN. In step 512, the GGSN sends back a create PDP context response message to the VSGSN. If the HGGSN is responsible for the allowance of the PDP address, this is included in the create PDP context response message. Otherwise, the corresponding field is set to 0.0.0.0 indicating that the mobile user needs to negotiate a PDP address with an external PDN after the completion of this procedure. Next, a Radio Access Bearer Setup procedure is undertaken in step 514. Step 514 can involve a QoS modification. If the QoS parameters were modified in step 514, the VSGSN and the HGGSN exchange update PDP context request and update PDP context response messages in order to modify these QoS parameters in the PDP context in steps 516 and 518, respectively. The VSGSN then sends an activate PDP context accept message to MN (or user equipment) to conclude the procedure in step 520.
It will be appreciated by those skilled in the art that this second described scenario can be caused by at least one of two situations. More specifically, the exchange of messages described in this second scenario occurs if either the user does not have the right to use the visited network's service (due to a prohibited VPLMN address for example) or if the mobile user has the right to use the services, but access to the VPLMN's access point is refused to the mobile user.
In the third scenario, a roaming user's communications are managed by a home GGSN when a user is in a visited PLMN as shown in
Then, in step 604, the mobile user sends an activate PDP context request message to the SGSN of the PLMN in which the mobile unit currently is located. Since the mobile user is roaming, it is an SGSN of the visited network (VSGSN) which deals with the Activate PDP context request message. Thereafter, the VSGSN checks the user's subscription records to establish the validity of the request. Once the validity of the mobile user's request is established, the VSGSN applies the GGSN selection mechanism, described above, in step 606. In step 608, the IP address of a VGGSN intended to provide the service whose ServiceID was selected (at step 400 of
Thus, the three step Home GGSN IP address discovery mechanism is launched in step 610. In the first part, step 610a, the VSGSN sends an ICMP Home GGSN address discovery request message containing the selected ServiceID to the SGSN unicast address of the mobile user's home PLMN. The home PLMN's SGSN receives the ICMP Home GGSN address discovery request message, in step 610b, and performs a search in its GGSN list using the received ServiceID. An ICMP Home GGSN address discovery response message is transmitted back to the originating VSGSN containing either the HGGSN's IP address or an error message in step 610c. If the ICMP Home GGSN address discovery response message contains the HGGSN's IP address, the process continues, otherwise the PDP context activation procedure is terminated.
In step 612, the VSGSN sends a create PDP context request message to the HGGSN whose IP address was obtained in step 610. The HGGSN creates a new entry in its table of PDP contexts which will allow it to route the user's packets between the VSGSN and the network PDN. In step 614, the GGSN sends back a create PDP context response message to the VSGSN. If the HGGSN is responsible for the allowance of the PDP address, this is included in the create PDP context response message. Otherwise, the corresponding field is set to 0.0.0.0 indicating that the mobile user needs to negotiate a PDP address with an external PDN after the completion of this procedure. Next, a Radio Access Bearer Setup procedure is undertaken in step 616. Step 616 can involve a QoS modification. If the QoS parameters were modified in step 616, the VSGSN and the HGGSN exchange update PDP context request and update PDP context response messages in order to modify these QoS parameters in the PDP context in steps 618 and 620 respectively. The VSGSN then sends an activate PDP context accept message to mobile MN (or user equipment) to conclude the procedure in step 622.
According to the exemplary embodiments described above, three scenarios have been described for accessing a network from a piece of user equipment using a Serviceld, instead of an APN, to select a GGSN (either in the visited network or in the home network) to support services. According to these exemplary embodiments, the system uses a GGSN selection mechanism, generally depicted in
Initially, in step 702, an SGSN 108 receives a ServiceID from a piece of user equipment. The SGSN 108 then checks to determine if the mobile user is in its Home PLMN in step 704. If the result from step 704 is yes (i.e., the mobile user is in its Home PLMN) then in step 706 the SGSN 108 carries out a search in its GGSN list based upon the received ServiceID. If the result from the search in step 706 is positive, then the PDP context request message is created in step 708. If the result from the search in step 706 is negative, the PDP context activation request is rejected in step 710.
Returning now to step 704, if the result is no, then the user is in a VPLMN. In step 712, the SGSN determines whether or not the user can use the services provided by the VPLMN. If the result from step 712 is a yes, then the SGSN determines if access to the VPLMN's access point is authorized in step 714. If the result from step 714 is yes, then the SGSN searches in its GGSN list based upon the received ServiceID in step 716. A positive search result from step 716 results in a PDP context request message being created, as shown in step 708.
If any of steps 712, 714 or 716 result in a no or a negative decision, then in step 718 the SGSN checks to see if the access to the Home PLMN access point is authorized for the mobile user. If the result in step 718 is a yes, then the SGSN launches the Home GGSN IP address discovery mechanism in step 720 using the previously received ServiceID. Upon a successful receipt of the HGGSN IP address, the PDP context activation request message is created in step 722. If a no or negative result is obtained during either of steps 718 or 720, the PDP context activation request is rejected in step 710.
The foregoing exemplary embodiments provide various benefits associated with the use of a ServiceID, instead of an APN, to support roaming in, for example, UMTS systems. For example, as stated above, the ServiceID uses a number instead of the DNS address contained in the APN, which is geographically anchored. This difference typically provides for an efficiency improvement in the use of roaming services because at least one transmission step is taken out of the data path under those circumstances where it is no longer a requirement for data to be routed through the home GGSN.
The above-described exemplary embodiments are intended to be illustrative in all respects, rather than restrictive, of the present invention. Thus the present invention is capable of many variations in detailed implementation that can be derived from the description contained herein by a person skilled in the art. All such variations and modifications are considered to be within the scope and spirit of the present invention as defined by the following claims. No element, act, or instruction used in the description of the present application should be construed as critical or essential to the invention unless explicitly described as such. Also, as used herein, the article “a” is intended to include one or more items.
