CA2691502C - Controlling a packet flow from a user equipment - Google Patents
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Abstract
A method, device management server, Packet Data Network Gateway (PDN GW) and User Equipment (UE) for establishing a PDN connection having defined packet flow limitations from a UE to a PDN GW. When a misbehaving or malicious UE is operating in the Evolved Packet System (EPS), the invention enables the UE to retain a PDN connection with an EPS bearer open until the software in the UE has been updated. The server sends to the UE, a management object that includes a logic parameter (packet filters) for controlling a packet flow from the UE to the network, or a defined Access Point Name (APN) that enables the UE to obtain the packet filters from a PDN GW. In turn, the UE sends to the network, a request for a new PDN connection while requesting deactivation of any previously existing PDN connections. The UE transmits on the new PDN connection, only packets allowed by the logic parameter.
Description
Attorney Docket No. P28235CA1 CONTROLLING A PACKET FLOW FROM A USER EQUIPMENT
BACKGROUND
The present invention relates to radio telecommunication systems. More particularly, and not by way of limitation, the present invention is directed to a method, device, and node for controlling a packet flow from a User Equipment (UE) in a radio telecommunication system.
Today, several actors are involved in managing the software and hardware of a UE, such as a mobile telephone or other communication device in a wireless communication system. The software can be applications, services, and modules, including the operating system stored in and used by the UE. The UE's manufacturer typically installs a collection of software in the UE at the time the device is manufactured. Later, an end user may modify the UE's software by downloading to the UE, applications and the like from different sources via, for example, the Internet. The UE's manufacturer, the operator of the communication system to which the UE is subscribed or in which the UE is visiting, and/or an authorized third party, depending on business agreements, may also remotely modify part or all of the UE's software.
After such modifications and in other instances, the UE may behave improperly. From a system operator's point of view, for example, improper behavior may include the UE's diminishing the capacity of the communication system by increasing the number of control or other messages exchanged with the system.
Improper UE behavior can arise in a number of ways, such as unexpected interactions between software modules in the UE, malicious software modules, and the like.
A user might download a malicious or malformed application such as a Java application, which interacts with the network-protocol stack through open Application Programming Interfaces (APIs) in the UE. As a result, the UE may repeatedly send service requests to an operator's network.
Attorney Docket No. P28235CA1 Techniques for dealing with improper UE behavior by disabling services to a UE have been discussed in standardization organizations such as the Third Generation Partnership Project (3GPP). The 3GPP promulgates specifications for the GSM
telecommunications system and its enhancements such as Enhanced Data Rates for GSM Evolution (EDGE), the universal mobile telecommunications system (UMTS), the Long Term Evolution (LTE) access network, and systems employing wideband code-division multiple access (WCDMA).
The Third Generation Partnership Project Technical Specification, 3GPP TS
24.305, describes procedures for managing settings of the UE for remotely disabling selected UE capabilities, used over a 3GPP access, i.e., a circuit-switched (CS) and packet-switched (PS) domain over GERAN/UTRAN radio access.
The Open Mobile Alliance (OMA) has developed specifications for Device Management (DM) of communication devices, and versions 1.1.2 and 1.2 of those specifications define a protocol for managing configuration, data, and settings in communication devices. OMA standards and other information are available at http://www.openmobilealliance.org. OMA DM can be used to manage the configuration and Management Objects (MOs) of UEs from the point of view of different DM
Authorities, including setting initial configuration information in UEs, subsequently updating persistent information in UEs, retrieving management information from UEs, and processing events and alarms generated by UEs. An MO is generally a software object that may be written, for example, according to SyncML, which is a mark-up language specification of an XML-based representation protocol, synchronization protocol, and DM protocol, transport bindings for the protocols, and a device description framework for DM. Using OMA DM, third parties can configure UEs on behalf of end users. A third party, such as a network operator, service provider, and corporate information management department can remotely set UE parameters and install or upgrade software through suitable MOs in the UE.
The Evolved Packet System (EPS) has been defined since 3GPP release-8 as a system for mobile communication using packet data over an evolved GPRS
network. The core network is an evolved UMTS packet core network and the radio
BACKGROUND
The present invention relates to radio telecommunication systems. More particularly, and not by way of limitation, the present invention is directed to a method, device, and node for controlling a packet flow from a User Equipment (UE) in a radio telecommunication system.
Today, several actors are involved in managing the software and hardware of a UE, such as a mobile telephone or other communication device in a wireless communication system. The software can be applications, services, and modules, including the operating system stored in and used by the UE. The UE's manufacturer typically installs a collection of software in the UE at the time the device is manufactured. Later, an end user may modify the UE's software by downloading to the UE, applications and the like from different sources via, for example, the Internet. The UE's manufacturer, the operator of the communication system to which the UE is subscribed or in which the UE is visiting, and/or an authorized third party, depending on business agreements, may also remotely modify part or all of the UE's software.
After such modifications and in other instances, the UE may behave improperly. From a system operator's point of view, for example, improper behavior may include the UE's diminishing the capacity of the communication system by increasing the number of control or other messages exchanged with the system.
Improper UE behavior can arise in a number of ways, such as unexpected interactions between software modules in the UE, malicious software modules, and the like.
A user might download a malicious or malformed application such as a Java application, which interacts with the network-protocol stack through open Application Programming Interfaces (APIs) in the UE. As a result, the UE may repeatedly send service requests to an operator's network.
Attorney Docket No. P28235CA1 Techniques for dealing with improper UE behavior by disabling services to a UE have been discussed in standardization organizations such as the Third Generation Partnership Project (3GPP). The 3GPP promulgates specifications for the GSM
telecommunications system and its enhancements such as Enhanced Data Rates for GSM Evolution (EDGE), the universal mobile telecommunications system (UMTS), the Long Term Evolution (LTE) access network, and systems employing wideband code-division multiple access (WCDMA).
The Third Generation Partnership Project Technical Specification, 3GPP TS
24.305, describes procedures for managing settings of the UE for remotely disabling selected UE capabilities, used over a 3GPP access, i.e., a circuit-switched (CS) and packet-switched (PS) domain over GERAN/UTRAN radio access.
The Open Mobile Alliance (OMA) has developed specifications for Device Management (DM) of communication devices, and versions 1.1.2 and 1.2 of those specifications define a protocol for managing configuration, data, and settings in communication devices. OMA standards and other information are available at http://www.openmobilealliance.org. OMA DM can be used to manage the configuration and Management Objects (MOs) of UEs from the point of view of different DM
Authorities, including setting initial configuration information in UEs, subsequently updating persistent information in UEs, retrieving management information from UEs, and processing events and alarms generated by UEs. An MO is generally a software object that may be written, for example, according to SyncML, which is a mark-up language specification of an XML-based representation protocol, synchronization protocol, and DM protocol, transport bindings for the protocols, and a device description framework for DM. Using OMA DM, third parties can configure UEs on behalf of end users. A third party, such as a network operator, service provider, and corporate information management department can remotely set UE parameters and install or upgrade software through suitable MOs in the UE.
The Evolved Packet System (EPS) has been defined since 3GPP release-8 as a system for mobile communication using packet data over an evolved GPRS
network. The core network is an evolved UMTS packet core network and the radio
2 Attorney Docket No. P28235CA1 access network may be an evolved UTRAN (E-UTRAN), a non-3GPP access network (for example WLAN), or a combination of both. The 3GPP Technical Specifications, 3GPP TS 23.401 and 3GPP TS 24.301, describe the GPRS enhancements for E-UTRAN access.
To stay registered in the EPS, an EPS bearer must be retained, as otherwise the EPS mobility procedures will be rejected by the EPS network, as described in 3GPP
TS 23.401. Also, as described in 3GPP TS 24.305, the OMA DM server controlling the Selective Disabling of a 3GPP UE Capabilities Management Object (SDoUE MO) needs to be able to push down updates of the MO to the UE. The push of MO updates using SMS cannot always be assumed to be available unless both the UE and the network support SMS using CS Fallback capabilities described in 3GPP TS 23.272, and even then a PS access is required to be open. Thus, the MO update may need to be sent over the PS access. Therefore, the PS access open in the UE needs to be accessible by the OMA DM server. Consequently, an EPS bearer towards a Packet Data Network (PDN) needs to be retained until the software in the UE has been updated. This may imply a risk of flooding the network with malicious traffic if the UE has been hacked.
BRIEF SUMMARY OF THE INVENTION
The present invention solves or at least mitigates the risk of flooding the radio access network and core network with malicious UE-initiated traffic. The invention enables the UE to retain a PDN connection with an EPS bearer open that enables the OMA DM server to communicate with the UE and ensure the EPS mobility procedure works. In one embodiment, the invention provides the operator with the ability to provision an Access Point Name (APN) and a Traffic Flow Template (TFT) to be used until the operator has enabled UE-initiated EPS services again.
Thus, in one embodiment, the present invention is directed to a method in a UE for limiting packet flow from the UE to a communication network. The method includes the steps of receiving from the network, an instruction to activate a logic parameter for controlling the packet flow from the UE to the network;
requesting configuration of a network connection for transmitting packets to the network according
To stay registered in the EPS, an EPS bearer must be retained, as otherwise the EPS mobility procedures will be rejected by the EPS network, as described in 3GPP
TS 23.401. Also, as described in 3GPP TS 24.305, the OMA DM server controlling the Selective Disabling of a 3GPP UE Capabilities Management Object (SDoUE MO) needs to be able to push down updates of the MO to the UE. The push of MO updates using SMS cannot always be assumed to be available unless both the UE and the network support SMS using CS Fallback capabilities described in 3GPP TS 23.272, and even then a PS access is required to be open. Thus, the MO update may need to be sent over the PS access. Therefore, the PS access open in the UE needs to be accessible by the OMA DM server. Consequently, an EPS bearer towards a Packet Data Network (PDN) needs to be retained until the software in the UE has been updated. This may imply a risk of flooding the network with malicious traffic if the UE has been hacked.
BRIEF SUMMARY OF THE INVENTION
The present invention solves or at least mitigates the risk of flooding the radio access network and core network with malicious UE-initiated traffic. The invention enables the UE to retain a PDN connection with an EPS bearer open that enables the OMA DM server to communicate with the UE and ensure the EPS mobility procedure works. In one embodiment, the invention provides the operator with the ability to provision an Access Point Name (APN) and a Traffic Flow Template (TFT) to be used until the operator has enabled UE-initiated EPS services again.
Thus, in one embodiment, the present invention is directed to a method in a UE for limiting packet flow from the UE to a communication network. The method includes the steps of receiving from the network, an instruction to activate a logic parameter for controlling the packet flow from the UE to the network;
requesting configuration of a network connection for transmitting packets to the network according
3 Attorney Docket No. P28235CA1 to the logic parameter; and requesting deactivation of all other network connections.
The logic parameter may be in a management object, and may be pre-stored in the UE, or may accompany the instruction.
In another embodiment, the present invention is directed to a UE that includes means for receiving from a communication network, an instruction to activate a logic parameter for controlling a packet flow from the UE to the network; means for requesting configuration of a network connection for transmitting packets to the network according to the logic parameter; and means for requesting deactivation of all other network connections.
In another embodiment, the present invention is directed to a device management server in a communication network for remotely controlling a packet flow from a mobile communication device. The server includes means for storing a management object that includes at least one of: a flag, a defined Access Point Name (APN), and a logic parameter for controlling the packet flow from the mobile communication device to the network; and means for downloading the management object to the mobile communication device. The flag, when downloaded to the mobile communication device, causes the device to activate the logic parameter in the management object or to activate a stored logic parameter in the device. The defined APN, when downloaded to the mobile communication device, causes the device to send a request to establish a new connection to the network on which packet flow from the device is controlled according to the logic parameter.
In another embodiment, the present invention is directed to a Packet Data Network (PDN) Gateway. The PDN Gateway includes means for receiving from a UE, a PDN connectivity request to establish a new PDN connection; and means for limiting a packet flow from the UE on the new PDN connection according to defined parameters.
BRIEF DESCRIPTION OF THE SEVERAL VIEWS OF THE DRAWING
In the following section, the invention will be described with reference to exemplary embodiments illustrated in the figures, in which:
The logic parameter may be in a management object, and may be pre-stored in the UE, or may accompany the instruction.
In another embodiment, the present invention is directed to a UE that includes means for receiving from a communication network, an instruction to activate a logic parameter for controlling a packet flow from the UE to the network; means for requesting configuration of a network connection for transmitting packets to the network according to the logic parameter; and means for requesting deactivation of all other network connections.
In another embodiment, the present invention is directed to a device management server in a communication network for remotely controlling a packet flow from a mobile communication device. The server includes means for storing a management object that includes at least one of: a flag, a defined Access Point Name (APN), and a logic parameter for controlling the packet flow from the mobile communication device to the network; and means for downloading the management object to the mobile communication device. The flag, when downloaded to the mobile communication device, causes the device to activate the logic parameter in the management object or to activate a stored logic parameter in the device. The defined APN, when downloaded to the mobile communication device, causes the device to send a request to establish a new connection to the network on which packet flow from the device is controlled according to the logic parameter.
In another embodiment, the present invention is directed to a Packet Data Network (PDN) Gateway. The PDN Gateway includes means for receiving from a UE, a PDN connectivity request to establish a new PDN connection; and means for limiting a packet flow from the UE on the new PDN connection according to defined parameters.
BRIEF DESCRIPTION OF THE SEVERAL VIEWS OF THE DRAWING
In the following section, the invention will be described with reference to exemplary embodiments illustrated in the figures, in which:
4 Attorney Docket No. P28235CA1 FIG. 1 is a tree diagram of an enhanced Selective Disabling of 3GPP UE
Capabilities Management Object (SDoUE MO+) in an exemplary embodiment of the present invention, with nodes added by the present invention indicated in boldface type;
FIG. 2 is a flow chart illustrating the steps of an exemplary embodiment of the method of the present invention; and FIG. 3 is a simplified block diagram of a User Equipment (UE) and associated nodes in a network in an exemplary embodiment of the present invention.
DETAILED DESCRIPTION OF THE INVENTION
For economy of explanation, this application focuses on wireless communication systems that comply with specifications promulgated by the 3GPP, but it should be understood that the principles described in this application can be implemented in other communication systems. It will also be understood that this description is written in terms of OMA DM, but this description should not be interpreted as being limited to OMA DM. Independent of the mechanism used to disable or enable services in a UE, it is advantageous for the UE to be selectively controllable in a standardized way.
The present invention updates 3GPP TS 24.305 procedures to handle the difference between EPS (3GPP TS 24.301) and GPRS (3GPP TS 24.008). The disabling of EPS is different than for GPRS. In EPS, the UE can request procedures for EPS contexts, but only the network can initiate them (this, in normal cases, includes the case of deactivation). Therefore, in exemplary embodiments of the present invention, the operator is provided with the ability to disable mobile-requested EPS
Session Management (SM) procedures. In one embodiment, a logic parameter is downloaded to the UE, causing the UE to request a new PDN connection towards the network with either a defined APN or no APN if the defined APN is not available for the UE.
The UE
requests deactivation of all previously existing PDN connections, and utilizes a particular traffic flow mapping for an EPS context that provides the network operator with control of packet access from UE applications.
Attorney Docket No. P28235CA1 In another embodiment, the logic parameter causes the UE to send the defined APN in the request for a new PDN connection. The defined APN causes the network to establish the new PDN connection with a particular PDN GW, configured to control the traffic flow from the UE in accordance with the particular traffic flow mapping.
Optionally, the PDN GW may push traffic flow mapping parameters to the UE.
It should be noted that in different configurations of the 30PP network architecture, the gateway may utilize either the GPRS Tunneling Protocol (GTP) or the Proxy Mobile IF (PM IF) protocol as a network mobility protocol. When GTP is utilized, it is the PDN GW that may push traffic flow mapping parameters to the UE. When PMIP
is utilized, the Serving GW may provide this part of the PDN GW functionality.
Thus, when the PDN GW is referred to herein, the term is intended to include the functionality of pushing traffic flow mapping parameters to the UE, whether the push is made by the PDN GW or by the Serving GW.
In another embodiment, the logic parameter causes the UE to utilize an existing PDN connection towards the network rather than establishing a new connection. Again, the UE requests deactivation of other PDN connections, if any, and utilizes a particular traffic flow mapping for an EPS context that provides the network operator with control of packet access from UE applications.
In another embodiment, the OMA DM server may know that the UE includes an internal application to ensure that only the application(s) controlling the connection towards the OMA DM server, and potentially emergency calls, are allowed access to use the PS connection. In such case, the OMA DM server does not have to download any APN or logic parameter to the UE. Instead, the OMA DM server may send only a flag instructing the UE to activate the internal application.
Once the network operator has control of packet access from UE
applications, the operator can prevent a misbehaving UE from flooding the network with malicious or erroneous traffic. As part of the correction process, a device management server such as an OMA DM server can push corrective software to the UE to correct or replace a corrupted application causing the misbehavior. In addition, the logic Attorney Docket No. P28235CA1 parameter may also limit the packet flow to a maximum data rate or a maximum packet size.
FIG. 1 is a tree diagram of an enhanced Selective Disabling of 3GPP UE
Capabilities Management Object (SDoUE MO+) in an exemplary embodiment of the present invention, with nodes added by the present invention indicated in boldface type.
Those skilled in the art will understand that the modified SDoUE MO+ is a software module that includes parameters that can be used to manage settings of the UE
for remotely disabling and enabling selected capabilities of the UE. The identifier for an existing SDoUE MO is "urn:oma:mo:ext-3gpp-sdoue:1.0". The OMA DM Access Control List (ACL) property mechanism as standardized (see Enabler Release Definition OMA-ERELD-DM-V1 2 [8]) may be used to grant or deny access rights to OMA DM
servers in order to modify nodes and leaf objects of the SDoUE MO.
In an exemplary embodiment of the present invention, the existing SDoUE
MO is enhanced to support the case of EPS with the addition of the following new nodes: EPS _ SM _EPS, APN, TrafficMappingInfo, Number0fPacketFilters, and PacketFilterList. When downloaded to the UE, the enhanced SDoUE MO+ adds at least the following capabilities to a device management server such as an OMA
DM
server:
1. The capability to separately disable UE-initiated EPS procedures such as UE-requested PDN connectivity, UE-requested bearer resource modification, and UE-requested PDN disconnect, as well as to provide restriction to EPS
services.
2. The capability to provision a special APN to which the UE can set up a =
PDN connection. This enables the PDN Gateway (PDN GW) to restrict the UE
traffic to only traffic necessary for communication with the OMA DM server and potentially IP
Multimedia Subsystem (IMS) emergency calls.
3. The capability to locally install the essential Uplink Traffic Flow Template (UL TFT) parameters in the UE to restrict the UE's ability to send IP packets other than those allowed by the operator, for example those required towards the OMA DM
server.
If an APN is provided in the SDoUE MO+, the PDN connection may be established with a PDN GW that is pre-configured with TFT-type information that can be Attorney Docket No. P28235CA1 set on the EPS bearer. However, if no APN is provided, the operator may establish the PDN connection to another PND GW utilizing a default APN.
With continuing reference to FIG. 1, the following paragraphs describe additions required to the indicated sections of 3GPP TS 24.305 in order to describe the new nodes and leaf objects of the enhanced SDoUE MO+ management object:
/<X>/EPS_SM_EPS
The EPS Session Management (SM) procedures for EPS contexts (EPS SM EPS) interior node 11 is a flag indicating an operator's preference to enable _ _ or disable mobile-requested EPS SM procedures for EPS contexts, i.e., UE-requested PDN connectivity, UE-requested bearer resource modification, and UE-requested PDN
disconnect, as well as to provide restriction to EPS services.
The EPS SM procedures for EPS contexts are specified in 3GPP TS 24.301 [5A].
- Occurrence: ZeroOrOne - Format: bool - Access Types: Get - Values: 0, 1 0 ¨ Indicates that mobile-requested EPS SM procedures for EPS contexts are enabled and no restriction to EPS services applies.
1 ¨ Indicates that mobile-requested EPS SM procedures for EPS contexts are disabled and restriction to EPS services applies.
/<X>/APN
The APN leaf object 12 provides the information of an access point name.
- Occurrence: ZeroOrOne - Format: chr - Access Types: Get - Values: <Access point name>
The format of the APN is defined by 3GPP TS 23.003 [2A] in clause 9.
Attorney Docket No. P28235CA1 EXAMPLE: mycompany.mnc012.mcc340.gprs /<X>/TrafficMappingInfo The TrafficMappingInfo interior node 13 is used to enable configuring the minimum acceptable traffic flow template (TFT) parameters (packet filters) for EPS
context according to the operator's preference.
- Occurrence: ZeroOrOne - Format: node - Access Types: Get - Values: N/A
The information provided by the TrafficMappingInfo interior node is used by the UE only when the EPS_SM_EPS leaf value is set to "1".
/<X>/Number0fPacketFilters The Number0fPacketFilters leaf object 14 indicates the number of traffic filters contained in the PacketFilterList leaf 15.
- Occurrence: One - Format: int - Access Types: Get - Values: <Number of packet filters>
The Number0fPacketFilters is an unsigned 8-bit integer, and the value range is defined as the number of packet filters parameter in the traffic flow template information element (see subclause 10.5.6.12 in 3GPP TS 24.008 [3]).
EXAMPLE: 3 (packet filters) /<X>/PacketFilterList The PacketFilterList leaf object 15 provides the information of a variable number of traffic filters.
- Occurrence: One - Format: int Attorney Docket No. P28235CA1 - Access Types: Get - Values: <Packet filter list information>
The PacketFilterList is an unsigned 64-bit integer. The bit pattern shall be encoded as the packet filter list parameter in the traffic flow template information element (see subclause 10.5.6.12 in 3GPP TS 24.008 [3]) with the least significant bit in the rightmost position of the integer. For example, if the parameter is encoded into bits 6, 7, and 8 in 3GPP TS 24.008 [3], then it must be encoded into bits 1, 2, and 3 in this leaf.
FIG. 2 is a flow chart illustrating the steps of an exemplary embodiment of the method of the present invention. When the value of the EPS_SM_EPS leaf 11 is set to "1", the method proceeds as follows:
At step 21, the OMA DM server sends the modified SDoUE MO+ to the UE.
At step 22, the UE initiates a new UE-requested PDN connectivity procedure toward the network as described in 3GPP TS 24.301 [6A]. At step 23, it is determined whether the APN leaf 12 exists in the modified SDoUE MO+. If the APN leaf 12 does not exist, the method moves to step 24 where the UE sends a PDN CONNECTIVITY REQUEST
message without including any APN in the message, and the network utilizes a default APN for establishing an EPS context with a PDN GW at step 25. However, if the APN
leaf exists, the method moves instead to step 26 where the UE sends the PDN
CONNECTIVITY REQUEST message and includes the value defined in the APN leaf as the APN in the message. At step 27, the network utilizes the defined APN for establishing an EPS context with a PDN GW associated with the defined APN.
After successful completion of the UE-requested PDN connectivity procedure at step 27, it is determined at step 28 whether the TrafficMappingInfo interior node 13 exists in the modified SDoUE MO+. The TrafficMappingInfo interior node, as shown in FIG. 1, provides at least one logic parameter for controlling the packet flow from the UE.
If the TrafficMappingInfo node does not exist, the method moves to step 29 where the UE transmits packets on the new PDN connection without filtering the packets.
At step 31, the PDN GW associated with the defined APN may optionally be configured to Attorney Docket No. P28235CA1 control the traffic flow from the UE or to download to the UE, a logic parameter for controlling the traffic flow from the UE. At step 32, the UE utilizes the logic parameter (i.e., traffic mapping information filters) to limit packet transmissions on the EPS context established by the UE-requested PDN connectivity procedure. Returning to step 28, if it is determined that the TrafficMappingInfo interior node does exist in the SDoUE MO+, the method moves directly to step 32.
Furthermore, the UE continues to limit packet transmissions on the EPS
context in accordance with the logic parameter until the EPS_SM_EPS leaf value is reset to "0". The UE is however allowed to temporarily stop using the traffic mapping information in the following cases:
- upon receipt of an OMA DM notification message indicating that the UE
shall initiate an OMA DM session to the OMA DM server that either had set the disable value of the EPS SM EPS leaf or is the one stored in the AlertServerlD leaf;
and _ _ - when the UE wishes to either establish an emergency call over IMS (if the IMSEmergencyCalls value is set to "0") or send an OMA DM generic alert message according to sub-clause 5.17A of 3GPP TS 24.305.
At step 33, the UE initiates the signaling procedure for UE-requested PDN
disconnection as described in 3GPP TS 24.301 [6A] of all previously existing PDN
connections, thus leaving only the new one, which was established by the successful completion of the UE-requested PDN connectivity procedure. At step 34, the EPS
context provides the network operator with control of packet access from UE
applications. As noted above, in EPS, the UE can request procedures for EPS
contexts, but only the network can initiate them (for normal cases, this includes the case of deactivation). Therefore, in this exemplary embodiment of the present invention, the operator is provided with the ability to disable mobile-requested EPS Session Management (SM) procedures.
It should be noted that the invention is not restricted to a specific order of the PDN connectivity request procedure and the deactivation of existing bearers;
the only restriction is that the UE always need to keep at least one PDN connection to avoid getting detached from the EPS. A different order may be required in case the UE
Attorney Docket No. P28235CA1 and/or EPS is currently using the maximum number of EPS bearers supported by the UE and/or the EPS (e.g., Mobility Management Entity (MME), Serving GW, or PDN
GW). For example, the UE may receive a rejection of an initial PDN
connectivity request, and in response, first deactivate one of the available PDN
connections to free up resources before initiating the PDN connectivity procedure for the PDN
connection to be used towards the OMA DM server.
FIG. 3 is a simplified block diagram of a UE 41 and associated nodes in a network 42 in an exemplary embodiment of the present invention. For simplicity, only those components in the UE and those nodes in the network that are associated with the present invention are shown. The network includes a device management server such as an OMA DM Server 43, the operation of which may be controlled by a processor 44. A memory 45 may store management objects such as the SDoUE MO+
of the present invention. An MO downloading unit 46 downloads the SDoUE MO+ 47 to the UE 41.
Receipt of the SDoUE MO+ in the UE causes a PDN connectivity request unit 48 to initiate a new PDN connectivity procedure by sending a PDN CONNECTIVITY
REQUEST message 49 to the network 42. The network establishes a new EPS
Context 51 between the UE and a PDN GW. Upon establishment of the new EPS
Context, a previous PDN connections deactivation unit 53 sends a PDN
disconnection request 54 to the network to disconnect any previously established PDN
connections.
This leaves only the new EPS Context in place between the UE and the network, and packet transmissions from the UE over this context are controlled by the logic parameter (packet filters) in the SDoUE MO+. Thus, the network has control of packet access through a packet filtering unit 55 as controlled by a processor 56 and applications 57.
In this manner, the present invention solves or at least mitigates the risk of flooding the radio access network and core network with malicious UE-initiated traffic.
The invention enables the UE to retain a PDN connection with an EPS bearer open until the software in the UE has been updated.
Attorney Docket No. P28235CA1 As will be recognized by those skilled in the art, the innovative concepts described in the present application can be modified and varied over a wide range of applications. Accordingly, the scope of patented subject matter should not be limited to any of the specific exemplary teachings discussed above, but is instead defined by the following claims.
Capabilities Management Object (SDoUE MO+) in an exemplary embodiment of the present invention, with nodes added by the present invention indicated in boldface type;
FIG. 2 is a flow chart illustrating the steps of an exemplary embodiment of the method of the present invention; and FIG. 3 is a simplified block diagram of a User Equipment (UE) and associated nodes in a network in an exemplary embodiment of the present invention.
DETAILED DESCRIPTION OF THE INVENTION
For economy of explanation, this application focuses on wireless communication systems that comply with specifications promulgated by the 3GPP, but it should be understood that the principles described in this application can be implemented in other communication systems. It will also be understood that this description is written in terms of OMA DM, but this description should not be interpreted as being limited to OMA DM. Independent of the mechanism used to disable or enable services in a UE, it is advantageous for the UE to be selectively controllable in a standardized way.
The present invention updates 3GPP TS 24.305 procedures to handle the difference between EPS (3GPP TS 24.301) and GPRS (3GPP TS 24.008). The disabling of EPS is different than for GPRS. In EPS, the UE can request procedures for EPS contexts, but only the network can initiate them (this, in normal cases, includes the case of deactivation). Therefore, in exemplary embodiments of the present invention, the operator is provided with the ability to disable mobile-requested EPS
Session Management (SM) procedures. In one embodiment, a logic parameter is downloaded to the UE, causing the UE to request a new PDN connection towards the network with either a defined APN or no APN if the defined APN is not available for the UE.
The UE
requests deactivation of all previously existing PDN connections, and utilizes a particular traffic flow mapping for an EPS context that provides the network operator with control of packet access from UE applications.
Attorney Docket No. P28235CA1 In another embodiment, the logic parameter causes the UE to send the defined APN in the request for a new PDN connection. The defined APN causes the network to establish the new PDN connection with a particular PDN GW, configured to control the traffic flow from the UE in accordance with the particular traffic flow mapping.
Optionally, the PDN GW may push traffic flow mapping parameters to the UE.
It should be noted that in different configurations of the 30PP network architecture, the gateway may utilize either the GPRS Tunneling Protocol (GTP) or the Proxy Mobile IF (PM IF) protocol as a network mobility protocol. When GTP is utilized, it is the PDN GW that may push traffic flow mapping parameters to the UE. When PMIP
is utilized, the Serving GW may provide this part of the PDN GW functionality.
Thus, when the PDN GW is referred to herein, the term is intended to include the functionality of pushing traffic flow mapping parameters to the UE, whether the push is made by the PDN GW or by the Serving GW.
In another embodiment, the logic parameter causes the UE to utilize an existing PDN connection towards the network rather than establishing a new connection. Again, the UE requests deactivation of other PDN connections, if any, and utilizes a particular traffic flow mapping for an EPS context that provides the network operator with control of packet access from UE applications.
In another embodiment, the OMA DM server may know that the UE includes an internal application to ensure that only the application(s) controlling the connection towards the OMA DM server, and potentially emergency calls, are allowed access to use the PS connection. In such case, the OMA DM server does not have to download any APN or logic parameter to the UE. Instead, the OMA DM server may send only a flag instructing the UE to activate the internal application.
Once the network operator has control of packet access from UE
applications, the operator can prevent a misbehaving UE from flooding the network with malicious or erroneous traffic. As part of the correction process, a device management server such as an OMA DM server can push corrective software to the UE to correct or replace a corrupted application causing the misbehavior. In addition, the logic Attorney Docket No. P28235CA1 parameter may also limit the packet flow to a maximum data rate or a maximum packet size.
FIG. 1 is a tree diagram of an enhanced Selective Disabling of 3GPP UE
Capabilities Management Object (SDoUE MO+) in an exemplary embodiment of the present invention, with nodes added by the present invention indicated in boldface type.
Those skilled in the art will understand that the modified SDoUE MO+ is a software module that includes parameters that can be used to manage settings of the UE
for remotely disabling and enabling selected capabilities of the UE. The identifier for an existing SDoUE MO is "urn:oma:mo:ext-3gpp-sdoue:1.0". The OMA DM Access Control List (ACL) property mechanism as standardized (see Enabler Release Definition OMA-ERELD-DM-V1 2 [8]) may be used to grant or deny access rights to OMA DM
servers in order to modify nodes and leaf objects of the SDoUE MO.
In an exemplary embodiment of the present invention, the existing SDoUE
MO is enhanced to support the case of EPS with the addition of the following new nodes: EPS _ SM _EPS, APN, TrafficMappingInfo, Number0fPacketFilters, and PacketFilterList. When downloaded to the UE, the enhanced SDoUE MO+ adds at least the following capabilities to a device management server such as an OMA
DM
server:
1. The capability to separately disable UE-initiated EPS procedures such as UE-requested PDN connectivity, UE-requested bearer resource modification, and UE-requested PDN disconnect, as well as to provide restriction to EPS
services.
2. The capability to provision a special APN to which the UE can set up a =
PDN connection. This enables the PDN Gateway (PDN GW) to restrict the UE
traffic to only traffic necessary for communication with the OMA DM server and potentially IP
Multimedia Subsystem (IMS) emergency calls.
3. The capability to locally install the essential Uplink Traffic Flow Template (UL TFT) parameters in the UE to restrict the UE's ability to send IP packets other than those allowed by the operator, for example those required towards the OMA DM
server.
If an APN is provided in the SDoUE MO+, the PDN connection may be established with a PDN GW that is pre-configured with TFT-type information that can be Attorney Docket No. P28235CA1 set on the EPS bearer. However, if no APN is provided, the operator may establish the PDN connection to another PND GW utilizing a default APN.
With continuing reference to FIG. 1, the following paragraphs describe additions required to the indicated sections of 3GPP TS 24.305 in order to describe the new nodes and leaf objects of the enhanced SDoUE MO+ management object:
/<X>/EPS_SM_EPS
The EPS Session Management (SM) procedures for EPS contexts (EPS SM EPS) interior node 11 is a flag indicating an operator's preference to enable _ _ or disable mobile-requested EPS SM procedures for EPS contexts, i.e., UE-requested PDN connectivity, UE-requested bearer resource modification, and UE-requested PDN
disconnect, as well as to provide restriction to EPS services.
The EPS SM procedures for EPS contexts are specified in 3GPP TS 24.301 [5A].
- Occurrence: ZeroOrOne - Format: bool - Access Types: Get - Values: 0, 1 0 ¨ Indicates that mobile-requested EPS SM procedures for EPS contexts are enabled and no restriction to EPS services applies.
1 ¨ Indicates that mobile-requested EPS SM procedures for EPS contexts are disabled and restriction to EPS services applies.
/<X>/APN
The APN leaf object 12 provides the information of an access point name.
- Occurrence: ZeroOrOne - Format: chr - Access Types: Get - Values: <Access point name>
The format of the APN is defined by 3GPP TS 23.003 [2A] in clause 9.
Attorney Docket No. P28235CA1 EXAMPLE: mycompany.mnc012.mcc340.gprs /<X>/TrafficMappingInfo The TrafficMappingInfo interior node 13 is used to enable configuring the minimum acceptable traffic flow template (TFT) parameters (packet filters) for EPS
context according to the operator's preference.
- Occurrence: ZeroOrOne - Format: node - Access Types: Get - Values: N/A
The information provided by the TrafficMappingInfo interior node is used by the UE only when the EPS_SM_EPS leaf value is set to "1".
/<X>/Number0fPacketFilters The Number0fPacketFilters leaf object 14 indicates the number of traffic filters contained in the PacketFilterList leaf 15.
- Occurrence: One - Format: int - Access Types: Get - Values: <Number of packet filters>
The Number0fPacketFilters is an unsigned 8-bit integer, and the value range is defined as the number of packet filters parameter in the traffic flow template information element (see subclause 10.5.6.12 in 3GPP TS 24.008 [3]).
EXAMPLE: 3 (packet filters) /<X>/PacketFilterList The PacketFilterList leaf object 15 provides the information of a variable number of traffic filters.
- Occurrence: One - Format: int Attorney Docket No. P28235CA1 - Access Types: Get - Values: <Packet filter list information>
The PacketFilterList is an unsigned 64-bit integer. The bit pattern shall be encoded as the packet filter list parameter in the traffic flow template information element (see subclause 10.5.6.12 in 3GPP TS 24.008 [3]) with the least significant bit in the rightmost position of the integer. For example, if the parameter is encoded into bits 6, 7, and 8 in 3GPP TS 24.008 [3], then it must be encoded into bits 1, 2, and 3 in this leaf.
FIG. 2 is a flow chart illustrating the steps of an exemplary embodiment of the method of the present invention. When the value of the EPS_SM_EPS leaf 11 is set to "1", the method proceeds as follows:
At step 21, the OMA DM server sends the modified SDoUE MO+ to the UE.
At step 22, the UE initiates a new UE-requested PDN connectivity procedure toward the network as described in 3GPP TS 24.301 [6A]. At step 23, it is determined whether the APN leaf 12 exists in the modified SDoUE MO+. If the APN leaf 12 does not exist, the method moves to step 24 where the UE sends a PDN CONNECTIVITY REQUEST
message without including any APN in the message, and the network utilizes a default APN for establishing an EPS context with a PDN GW at step 25. However, if the APN
leaf exists, the method moves instead to step 26 where the UE sends the PDN
CONNECTIVITY REQUEST message and includes the value defined in the APN leaf as the APN in the message. At step 27, the network utilizes the defined APN for establishing an EPS context with a PDN GW associated with the defined APN.
After successful completion of the UE-requested PDN connectivity procedure at step 27, it is determined at step 28 whether the TrafficMappingInfo interior node 13 exists in the modified SDoUE MO+. The TrafficMappingInfo interior node, as shown in FIG. 1, provides at least one logic parameter for controlling the packet flow from the UE.
If the TrafficMappingInfo node does not exist, the method moves to step 29 where the UE transmits packets on the new PDN connection without filtering the packets.
At step 31, the PDN GW associated with the defined APN may optionally be configured to Attorney Docket No. P28235CA1 control the traffic flow from the UE or to download to the UE, a logic parameter for controlling the traffic flow from the UE. At step 32, the UE utilizes the logic parameter (i.e., traffic mapping information filters) to limit packet transmissions on the EPS context established by the UE-requested PDN connectivity procedure. Returning to step 28, if it is determined that the TrafficMappingInfo interior node does exist in the SDoUE MO+, the method moves directly to step 32.
Furthermore, the UE continues to limit packet transmissions on the EPS
context in accordance with the logic parameter until the EPS_SM_EPS leaf value is reset to "0". The UE is however allowed to temporarily stop using the traffic mapping information in the following cases:
- upon receipt of an OMA DM notification message indicating that the UE
shall initiate an OMA DM session to the OMA DM server that either had set the disable value of the EPS SM EPS leaf or is the one stored in the AlertServerlD leaf;
and _ _ - when the UE wishes to either establish an emergency call over IMS (if the IMSEmergencyCalls value is set to "0") or send an OMA DM generic alert message according to sub-clause 5.17A of 3GPP TS 24.305.
At step 33, the UE initiates the signaling procedure for UE-requested PDN
disconnection as described in 3GPP TS 24.301 [6A] of all previously existing PDN
connections, thus leaving only the new one, which was established by the successful completion of the UE-requested PDN connectivity procedure. At step 34, the EPS
context provides the network operator with control of packet access from UE
applications. As noted above, in EPS, the UE can request procedures for EPS
contexts, but only the network can initiate them (for normal cases, this includes the case of deactivation). Therefore, in this exemplary embodiment of the present invention, the operator is provided with the ability to disable mobile-requested EPS Session Management (SM) procedures.
It should be noted that the invention is not restricted to a specific order of the PDN connectivity request procedure and the deactivation of existing bearers;
the only restriction is that the UE always need to keep at least one PDN connection to avoid getting detached from the EPS. A different order may be required in case the UE
Attorney Docket No. P28235CA1 and/or EPS is currently using the maximum number of EPS bearers supported by the UE and/or the EPS (e.g., Mobility Management Entity (MME), Serving GW, or PDN
GW). For example, the UE may receive a rejection of an initial PDN
connectivity request, and in response, first deactivate one of the available PDN
connections to free up resources before initiating the PDN connectivity procedure for the PDN
connection to be used towards the OMA DM server.
FIG. 3 is a simplified block diagram of a UE 41 and associated nodes in a network 42 in an exemplary embodiment of the present invention. For simplicity, only those components in the UE and those nodes in the network that are associated with the present invention are shown. The network includes a device management server such as an OMA DM Server 43, the operation of which may be controlled by a processor 44. A memory 45 may store management objects such as the SDoUE MO+
of the present invention. An MO downloading unit 46 downloads the SDoUE MO+ 47 to the UE 41.
Receipt of the SDoUE MO+ in the UE causes a PDN connectivity request unit 48 to initiate a new PDN connectivity procedure by sending a PDN CONNECTIVITY
REQUEST message 49 to the network 42. The network establishes a new EPS
Context 51 between the UE and a PDN GW. Upon establishment of the new EPS
Context, a previous PDN connections deactivation unit 53 sends a PDN
disconnection request 54 to the network to disconnect any previously established PDN
connections.
This leaves only the new EPS Context in place between the UE and the network, and packet transmissions from the UE over this context are controlled by the logic parameter (packet filters) in the SDoUE MO+. Thus, the network has control of packet access through a packet filtering unit 55 as controlled by a processor 56 and applications 57.
In this manner, the present invention solves or at least mitigates the risk of flooding the radio access network and core network with malicious UE-initiated traffic.
The invention enables the UE to retain a PDN connection with an EPS bearer open until the software in the UE has been updated.
Attorney Docket No. P28235CA1 As will be recognized by those skilled in the art, the innovative concepts described in the present application can be modified and varied over a wide range of applications. Accordingly, the scope of patented subject matter should not be limited to any of the specific exemplary teachings discussed above, but is instead defined by the following claims.
Claims (18)
1. A method in a User Equipment (UE) for limiting excessive packet flow from the UE to a Packet Data Network (PDN), said method comprising the steps of:
receiving by the UE from the PDN, an instruction to activate a logic parameter for controlling the packet flow from the UE to the PDN, wherein the UE has at least one previously existing PDN connection;
requesting by the UE, configuration of a PDN connection for transmitting packets to the PDN according to the logic parameter in response to receiving the instruc-tion;
upon establishment of an Evolved Packet System (EPS) context with a PDN
Gateway associated with a defined Access Point Name (APN):
utilizing the logic parameter by the UE to limit packet transmissions from the UE on the EPS context; and requesting by the UE, deactivation of all other previously existing PDN
connections.
receiving by the UE from the PDN, an instruction to activate a logic parameter for controlling the packet flow from the UE to the PDN, wherein the UE has at least one previously existing PDN connection;
requesting by the UE, configuration of a PDN connection for transmitting packets to the PDN according to the logic parameter in response to receiving the instruc-tion;
upon establishment of an Evolved Packet System (EPS) context with a PDN
Gateway associated with a defined Access Point Name (APN):
utilizing the logic parameter by the UE to limit packet transmissions from the UE on the EPS context; and requesting by the UE, deactivation of all other previously existing PDN
connections.
2. The method as recited in claim 1, wherein the step of receiving the instruction to activate the logic parameter includes receiving by the UE, a flag to activate a previously configured internal application that triggers the requesting steps.
3. The method as recited in claim 1, wherein the step of receiving the instruction to activate the logic parameter includes receiving by the UE, a flag to activate a previously stored logic parameter.
4. The method as recited in claim 3, wherein the logic parameter controls the UE to halt all applications except an application for communicating with a device management server and an application for sending emergency transmissions.
5. The method as recited in claim 1, wherein the step of receiving the instruction to activate the logic parameter includes receiving by the UE, the logic parameter and a flag to activate the logic parameter.
6. The method as recited in claim 5, wherein the logic parameter and the flag to ac-tivate the logic parameter are received by the UE from a device management server.
7. The method as recited in claim 5, wherein the step of receiving the logic parame-ter and the flag includes:
receiving the logic parameter by the UE from the PDN Gateway; and receiving the flag to activate the logic parameter by the UE from a device man-agement server.
receiving the logic parameter by the UE from the PDN Gateway; and receiving the flag to activate the logic parameter by the UE from a device man-agement server.
8. The method as recited in claim 7, wherein the step of receiving the logic parame-ter from the PDN Gateway includes the steps of:
receiving by the UE from the device management server, the defined APN; and sending the defined APN from the UE to the PDN in a request to establish a new PDN connection, the defined APN causing the PDN to establish the new PDN
connection to a PDN Gateway configured to download the logic parameter to the UE.
receiving by the UE from the device management server, the defined APN; and sending the defined APN from the UE to the PDN in a request to establish a new PDN connection, the defined APN causing the PDN to establish the new PDN
connection to a PDN Gateway configured to download the logic parameter to the UE.
9. The method as recited in claim 1, wherein the step of requesting configuration of a PDN connection for transmitting packets to the PDN according to the logic parameter includes sending from the UE to the PDN, a request to establish a new PDN
connection according to the logic parameter.
connection according to the logic parameter.
10. The method as recited in claim 1, wherein the step of requesting configuration of a PDN connection for transmitting packets to the PDN according to the logic parameter includes sending from the UE to the PDN, a request to reconfigure one of the previously existing PDN connections according to the logic parameter.
11. The method as recited in claim 1, wherein a corrupted application in the UE trig-gered the PDN to send the instruction to activate the logic parameter, and the method further comprises the UE receiving software from the PDN to repair or replace the cor-rupted application
12. The method as recited in claim 1, wherein the defined APN is either specified by the UE or selected as a default by the PDN.
13. A User Equipment (UE), comprising a processor coupled to a non-transitory memory for storing computer program instructions, wherein when the processor exe-cutes the computer program instructions, the processor causes the UE to:
receive from a Packet Data Network (PDN), an instruction to activate a logic pa-rameter for controlling a packet flow from the UE to the PDN, wherein the UE
has at least one previously existing PDN connection;
request configuration of a PDN connection for transmitting packets to the PDN
according to the logic parameter in response to receiving the instruction;
upon establishment of an Evolved Packet System (EPS) context with a PDN
Gateway associated with a defined Access Point Name (APN):
utilize the logic parameter by the UE to limit packet transmissions from the UE on the EPS context and request deactivation of all other previously existing PDN connections.
receive from a Packet Data Network (PDN), an instruction to activate a logic pa-rameter for controlling a packet flow from the UE to the PDN, wherein the UE
has at least one previously existing PDN connection;
request configuration of a PDN connection for transmitting packets to the PDN
according to the logic parameter in response to receiving the instruction;
upon establishment of an Evolved Packet System (EPS) context with a PDN
Gateway associated with a defined Access Point Name (APN):
utilize the logic parameter by the UE to limit packet transmissions from the UE on the EPS context and request deactivation of all other previously existing PDN connections.
14. The UE as recited in claim 13, wherein the UE is configured to store the logic parameter in an inactive state until the instruction to activate the logic parameter is re-ceived
15. The UE as recited in claim 13, wherein the UE is configured to request configura-tion of the PDN connection by sending a request to establish a new PDN
connection to the PDN on which packet transmission by the UE is controlled according to the logic parameter.
connection to the PDN on which packet transmission by the UE is controlled according to the logic parameter.
16. The UE as recited in claim 13, wherein the UE is configured to request configura-tion of the PDN connection by sending a request to reconfigure one of the previously existing PDN connections to provide a reconfigured PDN connection on which packet transmission by the UE is controlled according to the logic parameter.
17. The UE as recited in claim 13, wherein a corrupted application in the UE per-formed actions that triggered the PDN to send the instruction to activate the logic pa-rameter, and the UE is also configured to receive software from the PDN to repair or replace the corrupted application.
18. The UE as recited in claim 13, wherein the defined APN is either specified by the UE or selected as a default by the PDN.
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| Application Number | Priority Date | Filing Date | Title |
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| US12/694,378 | 2010-01-27 | ||
| US12/694,378 US8289848B2 (en) | 2009-02-02 | 2010-01-27 | Controlling a packet flow from a user equipment |
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| CA2691502C true CA2691502C (en) | 2017-10-24 |
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