A serving gateway updates location information for a mobile device based on information in an update bearer request. The serving gateway receives a first update bearer request for a mobile device. The first update bearer request includes a first address associated with a micro cellular service base station to which the mobile device is in communication. The micro cellular service base station is associated with a physical location. The serving gateway sends a location notification to a location server, indicating that the mobile device is physically near the micro cellular service base station. The serving gateway receives a second update bearer request for the mobile device including an address associated with a macro cellular service base station. The serving gateway sends another location notification to the location server indicating that the mobile device is no longer at the physical location of the micro cellular service base station.

TECHNICAL FIELD

The present disclosure relates generally to presence/location detection of mobile devices.

BACKGROUND

Micro cellular service base stations are used to extend and/or augment cellular network service in locations that may or may not be adequately covered by macro cellular service base stations. Micro base stations may provide the same cellular data and voice services as the macro base stations (e.g., radio towers), for a smaller, more localized area. The coverage area of micro base stations and macro base stations may overlap, requiring the mobile device to determine which base station provides the best service. As the mobile device moves, it may change the base stations to which it is attached depending on a selection algorithm. The selection algorithm may include hysteresis to prevent rapid switching back and forth between base stations.

Location services allow service providers to customize offerings to users based on their current location. The use of micro base stations with known locations allows the network to provide location information to service providers without any direction from the mobile device of the user. Typically, the Mobility Management Entity is charged with making updates to a presence server that tracks the location information of user devices. The Mobility Management Entity may detect the location a particular mobile device when the device communicates with the micro base station at a particular location. After the mobile device has not communicated with the micro base station for a predetermined amount of time, the Mobility Management Entity may infer that the mobile device is no longer near that location.

DESCRIPTION OF EXAMPLE EMBODIMENTS

Overview

A computer-implemented method is provided for a serving gateway to update location information for a mobile device based on information in an update bearer request. The method comprises receiving a first update bearer request for a mobile device. The first update bearer request includes a first address associated with a micro cellular service base station to which the mobile device is in communication. The micro cellular service base station is associated with a physical location. The method further comprises sending a first location notification to a location server. The first location notification indicates that the mobile device is at the physical location associated with the micro cellular service base station. The serving gateway receives a second update bearer request for the mobile device. The second update bearer request includes a second address associated with a macro cellular service base station. The serving gateway sends a second location notification to the location server. The second location notification indicates that the mobile device is no longer at the physical location associated with the micro cellular service base station.

Example Embodiments

Rather than rely on the expiration of a timer to detect when a mobile device is no longer in the coverage area of a micro base station, the techniques presented herein provide for the serving gateway to determine when the mobile device has moved away from the micro base station. Hereinafter, the capability of the serving gateway to detect when a mobile device has moved away from a micro base station may be referred to as “walk-away detection.”

Walk-away detection may be achieved using system elements that have visibility of macro signaling, such as a physical or virtual entity referred to herein as the Mobility Management Entity. However, some service providers may not want to support such vendor proprietary functionality in the Mobility Management Entity. For example, supporting multi-vendor serving gateways may be preferable to multi-vendor Mobility Management Entities. The techniques presented herein provide for micro base station walk-away detection using the serving gateway as an element that has visibility into macro signaling.

A serving gateway is enhanced with functionality for location/presence based on the network address (e.g., Internet Protocol address) of tunnel endpoints. An interface is defined to integrate the serving gateway with a location/presence server. The location/presence server is operable to request to be notified when a specific mobile device (e.g., as identified by an International Mobile Subscriber Identity (IMSI)) is present on the system. The serving gateway may be configured with a set of different network addresses corresponding to micro base stations and/or gateways that aggregate a number of micro base stations. In addition to typical serving gateway functionality, the serving gateway includes the functionality to match mobile identifiers (e.g., IMSI values) signaled by a Mobility Management Entity during standardized signaling (e.g., create default bearer requests) together with the associated network address (e.g., IP address or Tunnel Endpoint Identifier (TEID)), such as in an update bearer request message. For those IMSIs identified as belonging to a watch list from the location/presence server, the serving gateway may match the IP/TEID address with its pre-configured address information and to include such matching information in the presence notification message to the location/presence server.

Using the techniques presented herein, the serving gateway is able to determine when an IMSI previously supported with a tunnel IP/TEID address associated with a micro base station gateway is now supported with a tunnel IP/TEID address not associated with a micro base station, indicating that the mobile device associated with the IMSI has left the coverage of the micro base stations and hence any service adaptation may be immediately updated to reflect the change in location of the mobile device.

In one example, the IMSI selection may be associated with a particular service portal. An enterprise may be interested in the presence of their employee's mobile device and so enters a Mobile Station International Subscriber Directory Number (MSISDN) in a portal, and the MSISDN is converted to an IMSI using well defined application programming interfaces. In another example, a hotel may be interested in a loyalty card member, and will recover the member's MSISDN from their loyalty card database and use a carrier-supplied application programming interface to translate the MSISDN into an IMSI to monitor for their presence.

Referring now toFIG. 1, a simplified block diagram of a system100in which a mobile device110is configured to access a public data network120though a 4G Long Term Evolution (LTE) network infrastructure. The mobile device110is also referred to as a User Equipment (UE) in LTE parlance. The network infrastructure includes a macro base station130(e.g., a radio tower) to communicate wirelessly and send/receive calls from the mobile device110. A micro base station140may also provide cellular coverage to the mobile device110for a relatively smaller area than the coverage area of the macro base station130. The micro base station140may optionally communicate with the rest of the network infrastructure through a Home Evolved Node B Gateway (HeNB GW)145.

A serving gateway150handles communications from both the micro base station140(e.g., through the HeNB GW145) and the macro base station130. The serving gateway150coordinates the call setup and bearers for the calls involving the mobile device110. Walk-away detection logic155in the serving gateway150determines when a mobile device110is communicating through the macro base station130instead of the micro base station140. A Mobility Management Entity160or similar physical device or software process may also coordinate various aspects of the communications sessions for the mobile device110.

A presence/location server170communicates with the serving gateway150to coordinate the location or presence of the mobile device110. The presence/location server170may also communicate with the Mobility Management Entity160. A public network gateway180communicates with the serving gateway150to generate and maintain the communication links between the mobile device110and the public data network120.

The selection of a serving gateway150to support a particular micro base station140may be configured in the Mobility Management Entity160. The configuration of the Mobility Management Entity160may be such that specific micro base stations always have their S1-U connections supported by specific serving gateway instances. Hence the system may include a mapping of micro base stations to serving gateways. When selecting a serving gateway to watch for a particular mobile device, the system may re-use this mapping/association. For example, via a portal, an enterprise may identify specific enterprise micro base stations as being of interest. The management system will be responsible for translating this information into a well known micro base station identity. The data used to configure the Mobility Management Entity may then be used to map this micro base station identity to one or more serving gateway instances that are responsible for supporting the S1-U connection for mobile devices attached to these micro base stations.

Referring now toFIG. 2, a simplified block diagram shows an example of a serving gateway150. The serving gateway150includes a processor210to process instructions relevant to the operations of the device, and memory220to store a variety of data and software instructions (e.g., call data, Policy and Charging Control records, location data, etc.), including walk-away logic155and gateway logic225. The serving gateway150also includes a network interface unit230configured to communicate with computing devices and network elements over a network. The network may include a wireless network, a wired network, a local area network, a wide area network, and/or other types of networks configured to communicate data between computing devices.

Memory220may include read only memory (ROM), random access memory (RAM), magnetic disk storage media devices, optical storage media devices, flash memory devices, electrical, optical, or other physical/tangible (e.g., non-transitory) memory storage devices. The processor210is, for example, a microprocessor or microcontroller that executes instructions for implementing the processes related to the location detection described herein. Thus, in general, the memory220may include one or more tangible (non-transitory) computer readable storage media (e.g., a memory device) encoded with software (e.g., the network path selection logic) comprising computer executable instructions and when the software is executed (by the processor210) it is operable to perform the operations described herein.

Referring now toFIG. 3, a ladder diagram shows messages between elements of the location system in determining the presence of a user equipment device (e.g., mobile device110) as it first connects to the public network through the micro base station. Since the serving gateway150is determining whether the mobile device110is near the micro base station (Micro)140, the presence server170sends a subscription message305to the serving gateway (SGW)150. The subscription message305includes an identifier for the mobile device110, such as its International Mobile Subscriber Identity (IMSI).

When the mobile device110determines that a micro base station140will provide cellular service, it sends a connection request310to the micro base station140. The micro base station140replies to the connection request with message315. The mobile device110acknowledges the completed initial connection to the micro base station140with message320. After the mobile device110completes the initial connection with the micro base station140, the micro base station140sends a session request message325to the Mobility Management Entity (MME)160, optionally through the gateway (HeNB GW)145, to connect to the public network gateway (PGW)180(e.g., a Public Data Network (PDN) Gateway). The session request message325may include an exchange of messages to determine various parameters of the session (e.g., authentication, cipher suites, etc.) that are unaffected by the location system described herein.

As part of the session setup, the Mobility Management Entity160sends a create default bearer request message330to the serving gateway150, including the identifier of the mobile device110. The serving gateway150forwards the create default bearer request330to the public network gateway180. The public network gateway180responds with a create default bearer response335sent to the Mobility Management Entity160through the serving gateway150. On receiving the create default bearer request330, the serving gateway150may match the mobile identifier in the request330to a list of mobile identifiers, e.g., provided in subscription message305. If the mobile identifier in the create default bearer request330is matched to an entry in a list of subscribed mobile identifiers, then the serving gateway150may send a presence notification340to the presence server170. The presence notification340includes the mobile identifier of the mobile device110and an indication that the mobile device110is at the location of the micro base station140.

After the default bearer is created, the Mobility Management Entity160sends a context setup request350to the micro base station140. In response, the micro base station140sends a radio bearer request360to the mobile device110, which responds with a radio bearer response365. The micro base station140completes the context setup by sending a context setup response message370to the Mobility Management Entity160. The Mobility Management Entity160sends an update bearer request380to the public network gateway180through the serving gateway150. The public network gateway180responds with an update bearer response385to the Mobility Management Entity160through the serving gateway150. The update bearer request380includes an address of the micro base station140, such as the Internet Protocol (IP) address or the Tunnel Endpoint Identifier (TEID) of a General Packet Radio Service Tunneling Protocol (GTP) tunnel. In one example, the GTP tunnel may be between the serving gateway150and the micro base station140or the HeNB gateway145.

If the update bearer request380is for a mobile device110that is subscribed to the location service, the serving gateway150sends presence notification390to the presence server170with the mobile identifier of the mobile device110and the location information of the micro base station140. In one example, the serving gateway150maintains a list of mobile identifiers that are subscribed to the location service. When a bearer request is received, the mobile identifier form the bearer request is compared to the list of subscribed mobile identifiers, and a match may trigger a presence update to the presence server170.

In another example, the serving gateway150maintains a list of micro base stations, including physical locations and network addresses (e.g., IP address, TEID, etc.) for each of the micro base stations. When a presence update is triggered (e.g., by matching the mobile identifier to a list of subscribed devices), the serving gateway150determines the physical location of mobile device110by comparing the address in the bearer request to the list of micro base stations/HeNB GWs. If the address matches a micro base station, then the presence update includes the physical location of the micro base station that matches the address.

Referring now toFIG. 4, a ladder diagram shows messages between elements of the location system in determining the presence of a user equipment device (e.g., mobile device110) as it leaves the coverage area of the micro base station and attaches to the macro base station. The mobile device110sends a connection request410to the macro base station130, which responds with a connection setup OK message415. The mobile device110acknowledges the completion of the connection to the macro base station130with message420. After the connection with the mobile device110, the macro base station130sends an initial message430to the Mobility Management Entity160including a Tracking Area Update request. The Mobility Management Entity160responds with a Tracking Area Update response435. The macro base station130and the Mobility Management Entity160may exchange additional messages, such as authentication and/or encryption setup messages, before the Mobility Management Entity160accepts the Tracking Area Update request.

After the Mobility Management Entity160accepts the Tracking Area Update, the macro base station130sends a radio bearer request440to the mobile device110. The mobile device110responds with a radio bearer response message445, allowing the macro base station130to complete the Tracking Area Update. The macro base station130completes the Tracking Area Update with message450to the Mobility Management Entity160, which triggers an update bearer request460to the public network gateway180through the serving gateway150. The serving gateway150forwards the update bearer request460to the public network gateway180, which responds with update bearer response465.

The serving gateway150also determines if the mobile device110is subscribed to the location service, e.g., by comparing its mobile identifier to a list of subscribed mobile identifiers. If the mobile device110is subscribed, then the serving gateway150sends a presence notification470to the presence server170including the mobile identifier of the mobile device110and an indication that the mobile device110is no longer near a micro base station.

In one example, the update bearer request460may be a request to modify the bearer or a request to end the session entirely and release the bearer resources. An update bearer request to end the session may be received at one serving gateway150when a different serving gateway is assigned to continue the session (e.g., the mobile device has moved to an area covered by base stations covered by the different serving gateway). In another example, the presence notifications may be sent in response to messages other than the update bearer requests. In general, any message that the serving gateway150receives that includes both an identifier of the mobile device110and an address of the base station that the mobile device110is using to connect to the cellular network may trigger a presence notification.

Referring now toFIG. 5, a flowchart is shown of an example process500of the operations of the serving gateway150in providing timely location notifications. In step510, the serving gateway150receives a first update bearer request for a mobile device in communication with a micro base station. The serving gateway150sends a first location notification to a location server in step520. The first location notification indicates that the mobile device is near the micro base station. In one example, the serving gateway150stores a list of network addresses for micro base stations and/or HeNB gateway devices, and matches the network address from the update bearer request to the list of network address. Alternatively, the serving gateway150may lookup the tracking area indicated in the update bearer response against a list of tracking areas serviced by micro base stations. Additionally, the serving gateway150may store a list of physical locations of micro base stations and provide a physical location of the micro base station in the first location notification, as well as an indication that the mobile device is communicating through a micro base station.

In step530, the serving gateway150receives a second update bearer request for the mobile device when the mobile device is communicating through a macro base station. The serving gateway150sends a second location notification to the location server in step540. The second location notification includes an indication that the mobile device is no longer communicating through the micro base station, and is no longer near the physical location of the micro base station.

In one example, the serving gateway150may determine when a mobile device previously supported by an address (e.g., IP address or TEID) associated with a micro base station is now supported by an address that is not associated with a micro base station, indicating that the mobile device has left the coverage area of the micro base station. In this way, the serving gateway150supports walk-away detection by immediately signaling the location server with a location notification without waiting for a predetermined amount of time without any messages from the micro base station.

Referring now toFIG. 6, a flowchart is shown of an example process600of the operations of the serving gateway150in providing a location service to subscribed mobile devices. In step610, the serving gateway150receives a subscription request for a location service on a mobile device. The subscription request may be received from a location/presence server. The subscription request may identify the subscribed mobile device by a mobile identifier such as its IMSI. The subscription requests may be collected in a list of subscribed mobile devices.

In step620, the serving gateway150receives an update bearer request that includes a mobile device identifier and an address corresponding to the base station through which the mobile device connects to the cellular network. In one example, the address may include an Internet Protocol (IP) address, a TEID address, or a tracking area code. In step630, the serving gateway150compares the identifier of the mobile device to a list of subscribed mobile devices. If the mobile identifier in the update bearer request does not match to any entry in the list, then the process returns to wait for another update bearer request. If the mobile identifier in the update bearer request does match an entry in the list of subscribed devices, then the process600continues to determine which base station the mobile device is using to connect to the cellular network.

In step640, the serving gateway150compares the address of the base station included in the update bearer request to a list of addresses corresponding to micro base stations. If the address matches an entry in the list of micro base stations, then the serving gateway150sends a location notification to a location/presence server indicating that the subscribed mobile device is at the micro base station in step650. If the address in the update bearer request does not match any entry in the list of micro base stations, then the serving gateway150sends a location notification to the location/presence server indicating that the subscribed mobile device is not at a micro base station in step660.

In summary, a serving gateway includes enhanced functionality to enable location and presence detection to be signaled in networks without relying on any modification to the Mobility Management Entity. The same serving gateway functionality may be used to deliver walk-away detection from a micro base station. The system is also able to support notification subscriptions for particular mobile devices on the appropriate serving gateway instances. These techniques do not require other vendor's mobility management entities to activate location and presence capability. In fact, these techniques can support multi-vendor serving gateways and may be appealing to a service provider than multiple vendor mobility management entities. Moreover, these techniques enable rapid walk away detection. Again, these techniques exploit the opportunity to deliver small (micro) cell walk away detection using the serving gateway as an element that has visibility to macro network signaling.

In one form, a computer-implemented method is provided for a serving gateway to update location information for a mobile device based on information in an update bearer request. The method comprises receiving a first update bearer request for a mobile device. The first update bearer request includes a first address associated with a micro cellular service base station to which the mobile device is in communication. The micro cellular service base station is associated with a physical location. The method further comprises sending a first location notification to a location server. The first location notification indicates that the mobile device is at the physical location associated with the micro cellular service base station. The serving gateway receives a second update bearer request for the mobile device. The second update bearer request includes a second address associated with a macro cellular service base station. The serving gateway sends a second location notification to the location server. The second location notification indicates that the mobile device is no longer at the physical location associated with the micro cellular service base station.

In another form, an apparatus is provided comprising a network interface unit and processor is provided for updating location information of a mobile device based on information in an update bearer request. The network interface unit is configured to communicate with computing devices on one or more networks. The processor is configured to receive via the network interface unit, a first update bearer request. The first update bearer request includes a first address associated with a micro cellular service base station to which the mobile device is in communication. The micro cellular service base station is associated with a physical location. The processor is also configured to send a first location notification to a location server via the network interface unit. The first location notification indicates that the mobile device is at the physical location associated with the micro cellular service base station. The processor is further configured to receive via the network interface unit, a second update bearer request for the mobile device. The second update bearer request includes a second address associated with a macro cellular service base station. The processor is configured to send a second location notification to the location server via the network interface unit. The second location notification indicates that the mobile device is not longer at the physical location associated with the micro cellular service base station.

In yet another form, one or more non-transitory computer readable storage media are provided with software comprising computer executable instructions operable to cause a processor to update location information of a mobile device based on information in an update bearer request. The instructions are configured to cause the processor to receive a first update bearer request. The first update bearer request includes a first address associated with a micro cellular service base station to which the mobile device is in communication. The micro cellular service base station is associated with a physical location. The instructions are also configured to cause the processor to send a first location notification to a location server. The first location notification indicates that the mobile device is at the physical location associated with the micro cellular service base station. The instructions are further configured to cause the processor to receive a second update bearer request for the mobile device. The second update bearer request includes a second address associated with a macro cellular service base station. The instructions are configured to cause the processor to send a second location notification to the location server via the network interface unit. The second location notification indicates that the mobile device is not longer at the physical location associated with the micro cellular service base station.