1. Field of the Invention
This invention relates in general to Push-To-Talk over Cellular (PoC), and more specifically, to WiFi interworking solutions for PoC in the Open Mobile Alliance (OMA) Standard.
2. Description of Related Art
Advanced voice services (AVS), also known as Advanced Group Services (AGS), such as two-way half-duplex voice calls within a group, also known as Push-to-Talk-over-Cellular (PoC), Push-to-Talk (PTT), or Press-to-Talk (P2T), as well as other AVS functions, such as Push-to-Conference (P2C) or Instant Conferencing, Push-to-Message (P2M), etc., are described in the co-pending and commonly-assigned patent applications cross-referenced above and incorporated by reference herein. These AVS functions have enormous revenue earnings potential for wireless communications systems, such as cellular networks and personal communications systems (PCS) networks.
One approach to PoC is based on packet or voice-over-IP (VoIP) technologies. This approach capitalizes on the “bursty” nature of PoC conversations and makes network resources available only during talk bursts and hence is highly efficient from the point of view of network and spectral resources. This approach promises compliance with newer and emerging packet-based standards, such as GPRS (General Packet Radio Service), UMTS (Universal Mobile Telecommunications System), 3G, 4G, LTE, etc.
Nonetheless, there is a need in the art for improvements to the methods and systems for delivering the advanced voice services, such as PoC, that comply with both existing and emerging wireless packet-based standards and yet provide superior user experiences. Many existing implementations of PoC suffer from an inferior user experience. The present invention satisfies the need for a superior user experience, and also defines procedures for practical implementation of PoC in commercial, standards-based, cellular networks, with a focus on features such as WiFi interworking solutions.
To overcome the limitations in the prior art described above, and to overcome other limitations that will become apparent upon reading and understanding the present specification, the present invention discloses a Push-to-Talk-over-Cellular (PoC) implementation for use in wireless communications networks, such as cellular mobile phone networks, wireless data networks and WiFi networks, wherein one or more servers interface to the wireless communications networks to perform PoC call sessions. Both the servers and the mobile units that use the PoC call sessions communicate with each other using SIP/IP (Session Initiation Protocol/Internet Protocol) control messages within the wireless communications networks, and one or more of the servers switches RTP/IP (Realtime Transport Protocol/Internet Protocol) voice packets, RTCP/IP (Realtime Transport Control Protocol/Internet Protocol), or MBCP/IP (Media Burst Control Protocol/Internet Protocol) controlling/signaling packets for the PoC call sessions between the mobile units across the wireless communications networks.
Referring now to the drawings in which like reference numbers represent corresponding parts throughout:
In the following description of the preferred embodiment, reference is made to the accompanying drawings which form a part hereof, and in which is shown by way of illustration the specific embodiment in which the invention may be practiced. It is to be understood that other embodiments may be utilized as structural changes may be made without departing from the scope of the present invention.
1 Overview
The present invention discloses a system for implementing Push-to-Talk-over-Cellular (PoC) that provides a feature-rich server architecture with a flexible client strategy. This system is an Open Mobile Alliance (OMA) standards-compliant solution that can be easily deployed, thereby enabling carriers to increase their profits, improve customer retention and attract new customers without costly upgrades to their network infrastructure. This system is built on a proven, reliable all-IP (Internet Protocol) platform. The highly scalable platform is designed to allow simple network planning and growth. Multiple servers can be distributed across operator networks for broad geographic coverage and scalability to serve a large and expanding subscriber base.
The following table defines various acronyms, including industry-standard acronyms, that are used in this specification.
The following table defines various terms, including industry-standard terms, that are used in this specification.
2 System Architecture
Preferably, the system 100 includes one or more PoC Service Layers 102 and one or more Management Layers 104, each of which is comprised of one or more servers interconnected by one or more IP networks 106. Specifically, the PoC Service Layer 102 includes one or more XML Document Management (XDM) Servers 108, Presence Servers 110, PoC Servers 112, and Media Servers 114, while the Management Layer 104 includes one or more Element Management System (EMS) Servers 116, Lawful Intercept (LI) Servers 118, Web Customer Service Representative (WCSR) Servers 120, and Web Group Provisioning (WGP) Servers 122. These various servers are described in more detail below.
The PoC Service Layer 102 and Management Layer 104 are connected to one or more wireless communications networks, such as cellular phone networks 124 and wireless data networks 126, as well as one or more IP networks 106. Note that the cellular phone networks 124 and wireless data networks 126 may be implemented in a single network or as separate networks. The cellular phone network 124 includes one or more Short Message Service Centers (SMSCs) 128, Mobile Switching Centers (MSCs) 130, and Base Station Components (BSCs) 132, wherein the BSCs 132 include controllers and transceivers that communicate with one or more customer handsets 134 (also referred to as a mobile unit, mobile station, mobile phone, cellular phone, etc.) executing a PoC Client 136. The wireless data network 126, depending on its type, e.g., GPRS or 4G/LTE, includes one or more Gateway GPRS Support Nodes (GGSNs) or Packet Gateways (PGWs) 136 and Serving GPRS Support Nodes (SGSNs) or Wireless GateWays (WGWs) 138, which also communicate with customer handsets 134 via BSCs or eNodeBs 132.
Finally, in one embodiment of the present invention, the PoC Service Layer 102 and Management Layer 104 are connected to one or more RendeVous (RV) Servers 140, which are coupled to one or more WiFi networks 142, in order to communicate with one or more PoC Clients 136 on one or more handsets 134. Note that the WiFi networks 142 are IP networks, which may be implemented in a single network or as separate networks, and may include one or more Firewalls 144.
2.1 Cellular Phone Network
The PoC Service Layer 102 interacts with the SMSC 128 on the cellular phone network 124 to handle Short Message Service (SMS) operations, such as routing, forwarding and storing incoming text messages on their way to desired endpoints.
2.2 Wireless Data Network
The PoC Service Layer 102 also interacts with the following entities on the wireless data network 126:
2.3 WiFi Network
The PoC Service Layer 102 also interacts with the following entities on the WiFi network 142:
2.4 PoC Service Layer Elements
As noted above, the PoC Service Layer 102 is comprised of the following elements:
These elements are described in more detail below.
2.4.1 PoC Server
The PoC Server 112 handles the PoC call session management and is the core for managing the PoC services for the PoC Clients 136 using SIP protocol. The PoC Server 112 implements a Control Plane portion of Controlling and Participating PoC Functions. A Controlling PoC Function acts as an arbitrator for a PoC Session and controls the sending of control and bearer traffic by the PoC Clients 136. A Participating PoC Function relays control and bearer traffic between the PoC Client 136 and the PoC Server 112 performing the Controlling PoC Function.
2.4.2 Media Server
The Media Server 114 implements a User Plane portion of the Controlling and Participating PoC Functions. The Media Server 114 supports the Controlling PoC Function by duplicating voice packets received from an originator PoC Client 136 to all recipients of the PoC Session. The Media Server 114 also supports the Participating PoC Function by relaying the voice packets between PoC Clients 136 and the Media Server 114 supporting the Controlling PoC Function. The Media Server 114 also handles packets sent to and received from the PoC Clients 136 for floor control during PoC call sessions.
2.4.3 Presence Server
The Presence Server 110 implements a presence enabler for the PoC Service. The Presence Server 110 accepts, stores and distributes Presence Information for Presentities, such as PoC Clients 136.
The Presence Server 110 also implements a Resource List Server (RLS), which accepts and manages subscriptions to Presence Lists. Presence Lists enable a “watcher” application to subscribe to the Presence Information of multiple Presentities using a single subscription transaction.
The Presence Server 110 uses certain XDM functions to provide these functions, which are provided by XDM Server 108.
2.4.4 XDM Server
The XDM Server 108 implements an XDM enabler for the PoC Service. The XDM enabler defines a common mechanism that makes user-specific service-related information accessible to the functions that need them. Such information is stored in the XDM Server 108 where it can be located, accessed and manipulated (e.g., created, changed, deleted, etc.). The XDM Server 108 uses well-structured XML documents and HTTP protocol for access and manipulation of such XML documents. The XDM Server 108 also connects to the operator SMSC 128 for the purposes of PoC Client 136 activation using SMS. In addition, the XDM Server 108 maintains the configuration information for all PoC subscribers.
2.4.5 RV Server
The RV Server 140 implements a WiFi interworking solution for the PoC Service to communicate via one or more WiFi network 142 access points to the PoC Clients 136. Specifically, the RV Server 140 provides PoC Service over a WiFi network 142 (or similar Internet environments), and supports a seamless user experience while the transport of IP control messages and IP voice data is transitioned between different types of wireless communications networks, such as wireless data networks 126 comprising cellular data packet networks and WiFi networks 142. The RV Server 140 also resolves security concerns that arise with such WiFi interworking solutions.
This is necessary because the quality, performance and availability of the wireless data networks 126 typically vary from location to location based on various factors. In addressing these issues, the WiFi interworking solution implemented by the RV Server 140 provides following benefits:
These and other aspects of the WiFi interworking solution are described in more detail below.
2.5 Management Layer Elements
As noted above, the Management Layer 104 is comprised of the following elements:
These elements are described in more detail below.
2.5.1 EMS Server
The EMS Server 116 is an operations, administration, and maintenance platform for the system 100. The EMS Server 116 enables system administrators to perform system-related configuration, network monitoring and network performance data collection functions. The EMS Server 116, or another dedicated server, may also provide billing functions. All functions of the EMS Server 116 are accessible through a web-based interface.
2.5.2 LI Server
The LI Server 118 is used for tracking services required by various Lawful Enforcement Agents (LEAs). The LI Server 118 generates and pushes an IRI (Intercept Related Information) Report for all PoC Services used by a target. The target can be added or deleted in to the PoC Server 112 via the LI Server 118 using a Command Line Interface (CLI).
2.5.3 WGP Server
The WGP Server 122 provides a web interface for corporate administrators to manage
PoC contacts and groups. The web interface includes contact and group management operations, such as create, delete and update contacts and groups.
2.5.4 WCSR Server
The WCSR Server 120 provides access to customer service representatives (CSRs) for managing end user provisioning and account maintenance.
Typically, it supports the following operations:
3 System Functions
The following sections describe various functions performed by each of the components of the system architecture.
3.1 PoC Service Layer
3.1.1 PoC Server
The PoC Server 112 controls PoC call sessions, including 1-1, Ad Hoc and Pre-Arranged PoC call sessions. The PoC Server 112 also controls Instant Personal Alerts.
The PoC Server 112 expects the PoC Clients 136 to setup “pre-established sessions” at the time of start up and use these sessions to make outgoing PoC calls. The PoC Server 112 also uses pre-established sessions to terminate incoming PoC calls to the PoC Clients 136. The PoC Clients 136 are setup in auto-answer mode by default. The use of pre-established sessions and auto-answer mode together allow for faster call setup for PoC call sessions.
The PoC Server 112 allocates and manages the media ports of the Media Services 114 associated with each SIP INVITE dialog for pre-established sessions and controls the Media Servers 114 to dynamically associate these ports at run time for sending RTP packets during PoC call sessions. Media ports are assigned and tracked by the PoC Server 112 at the time of setting up pre-established sessions. The PoC Server 112 instructs the Media Server 114 to associate the media ports of various subscribers dynamically into a session when a PoC call is originated and this session is maintained for the duration of the call. The PoC Server 112 also controls the floor states of the various participants in a PoC call session by receiving indications from the Media Servers 114 and sending appropriate requests back to the Media Servers 114 to send MBCP messages to the participants in the PoC call. The Media Server 114 uses the media ports association and current talker information to send the RTP packets from the talker's media port onto the listeners' media ports.
In addition, the PoC Server 112 handles the incoming and outgoing Instant Personal Alerts (IPAs) by routing SIP MESSAGE requests to the PoC Clients 136 and remote PoC Servers 112 for final delivery as applicable.
The PoC Server 112 uses static and dynamic data related to each subscriber to perform these functions. Static data include subscriber profile, contacts and groups. Dynamic data include the subscriber's registration state, PoC settings and SIP dialog states are maintained only on the PoC Server 112.
3.1.2 Media Server
The Media Server 114 handles the flow of data to and from the PoC Clients 136 as instructed by the PoC Server 112. Each Media Server 114 is controlled by a single PoC Server 112, although multiple Media Servers 114 may be controlled by a PoC Server 112 simultaneously.
The Media Server 114 is completely controlled by the PoC Server 112. As noted above, even the media ports of the Media Server 114 are allocated by the PoC Server 112 and then communicated to the Media Server 114. Likewise, floor control requests received by the Media Server 114 from PoC Clients 136 are sent to the PoC Server 112, and the PoC Server 112 instructs the Media Server 114 appropriately. Based on these instructions, the Media Server 114 sends floor control messages to the PoC Clients 136 and sends the RTP packets received from the talker to all the listeners.
3.1.4 Presence Server
The Presence Server 110 accepts presence information published by PoC Clients 136, as well as availability information received from other entities. The Presence Server 110 keeps track of these presence states and sends notifications to various “watcher” applications whenever a presence state changes. The Presence Server 110 maintains a separate subscription for each watcher and dynamically applies the presence authorization rules for each watcher independently.
The Presence Server 110 also accepts resource list subscriptions from the watchers, which identify one or more entities (“Presentities”) whose presence should be monitored. The Presence Server 110 then aggregates all the presence information into one or more presence notifications transmitted to each watcher. This allows watchers to subscribe to large number of Presentities without putting strain on the network as well as client and server resources.
3.1.5 XDM Server
The XDM Server 108 performs client authentication and subscription functions. The XDM Server 108 also stores subscriber and group information data. The XDM Server 108 also interacts with the SMSC 128 to receive PoC Client 136 activation commands.
All subscriber provisioning and CSR operations in the XDM Server 108 are performed through the WCSR Server 120, while corporate administrative operations, as well as contacts and group management, are handled through the WGP Server 122.
The XDM Server 108 includes a Subscriber Profile Manager module that provides subscriber management functionality, such as creation, deletion and modification of subscriber profiles. The subscriber profile includes data such as the MDN, subscriber name, subscriber type, etc. This also determines other system-wide configurations applicable for the subscriber including the maximum number of contacts and groups per subscriber and the maximum number of members per group.
The XDM Server 108 includes a Subscriber Data Manager module that manages the subscriber document operations, such as contact and group management operations, initiated by the PoC Clients 136 or the WGP Server 122.
3.1.6 RV Server
The RV Server 140 performs WiFi interworking for the PoC service by communicating with the PoC Clients 136 via one or more WiFi networks 142.
The PoC Client 136 sets up one or more connections using the configured Fully Qualified Domain Name (FQDN), or absolute domain name, of the RV Server 140, which may be publicly exposed to the Internet. Secure transport protocols may (or may not) be used for the connections across the WiFi networks 142. For example, the PoC Clients 136 may use the Transport Layer Security (TLS) and/or Secure Sockets Layer (SSL) protocols for encrypting information transmitted over the connections between the PoC Client 136 and the RV Server 140.
In such an embodiment, all SIP signaling and voice data (RTP and RTCP) would be tunneled over the SSL/TLS connections between the PoC Client 136 and the RV Server 140. XCAP signaling may be transmitted using a Hypertext Transfer Protocol Secure (HTTPS) protocol, which results from layering the Hypertext Transfer Protocol (HTTP) on top of the SSL/TLS connections, thus adding the security capabilities of SSL/TLS to standard HTTP communications.
Consequently, the RV Server 140 performs as an encryption/decryption off-loader that provides end-to-end encryption for all traffic transmitted to and from the PoC Client 136. Specifically, all of the traffic sent to the PoC Client 136 is encrypted at the RV Server 140 and all the traffic received from the PoC Client 136 is decrypted at the RV Server 140.
The RV Server 140 terminates the SSL/TLS connections and aggregates or dis-aggregates the PoC Client 136 traffic to the appropriate Servers 108, 110, 112, 114, 116, 118, 120 and 122. Specifically, the RV Server 140 acts as an intelligent traffic distributor for SIP signaling and RTP/RTCP traffic by forwarding the traffic to the appropriate Servers 108, 110, 112, 114, 116, 118, 120 and 122, depending on the message types and the availability of the Servers 108, 110, 112, 114, 116, 118, 120 and 122. Consequently, the RV Server 140 is a single point-of-contact for all traffic to and from the PoC Clients 136 at an IP transport layer via the WiFi networks 142.
Typically, the SSL/TLS connections are persisted and used for any bidirectional data transfer between the RV Server 140, or other Servers, and the PoC Clients 136. Thus, a PoC Client 136 maintains an “always-on” connection with the RV Server 140 by periodically sending “keep-alive” messages over the SSL/TLS connections.
The present invention also simplifies the traversal of the Firewalls 144. Preferably, the PoC Clients 136 establish the SSL/TLS connections to the RV Server 140 over TCP port 443, which is typically used for HTTPS communications. This allows for Firewall 144 traversal on most corporate networks, because the Firewall 144 facing (exposed to) the Internet is default configured to allow (and not deny) the SSL/TLS connections on TCP port 443. As a result, the present invention does not require that any special changes be made to the Firewall 144, such as those changes typically required for VoIP deployments in corporate networks. Instead, the traffic with the PoC Clients 136 is routed over SSL/TLS connections on TCP port 443, which can traverse through the Firewalls 144 seamlessly.
3.2 Management Layer
3.2.1 EMS Server The EMS Server 116 is the central management entity in the system and includes the following modules:
3.2.2 WCSR Server
The WCSR Server 120 provides a web user interface for customer service representatives (CSRs) to carry out various operations. The web user interface provides access to CSRs for managing subscriber provisioning and account maintenance. Typically, it supports the following operations.
3.2.3 WGP Server
The WGP Server 122 allows provides for central management of all corporate subscribers and associated contacts and groups within a corporation. The WGP Server 122 allows corporate administrators to manage contacts and groups for corporate subscribers.
The WGP Server 122 includes a Corporate Administration Tool (CAT) that is used by corporate administrators to manage contacts and groups of corporate subscribers. The CAT has a Web User Interface for corporate administrators that supports the following operations:
With regard to group management, the CAT of the WGP Server 122 includes the following operations:
With regard to contact management, the CAT of the WGP Server 122 includes the following operations:
With regard to associations between corporations, the CAT of the WGP Server 122 includes the following operations:
Once the association is created and accepted, corporate administrators can create contacts and groups using the association policies. Administrators from other corporations can view the contacts, and may or may not have the capability to add, update or delete the contacts.
Note that, if the association is deleted, then usually all intercorporate contacts and group members will be deleted.
3.3 PoC Client
The PoC Client 136 is an OMA-compatible client application executed on a handset 134. The following features are supported by the PoC Client 136:
The PoC Client 136 includes a database module, a presence module, an XDMC module and a client module.
The database module stores configuration information, presence information, contact and group information, user settings, and other information in an optimized and persistent way. Information is preserved when the user unregisters with the PoC Server 112 or power cycles the device. The database module also has a mechanism to reset the data and synchronize from the XDM Server 108 when the data in the database module is corrupt or unreadable.
The presence module creates and maintains the presence information for the subscriber. Typically, the presence information supports Available, Unavailable and Do-not-Disturb (DnD) states. The presence module also subscribes to the Presence Server 110 as a “watcher” of all contacts in the handset 134 and updates the user interface of the handset 134 whenever it receives a notification with such presence information.
The XDMC module communicates with the XDM Server 108 for management of contacts and groups. The XDMC module may subscribe with the XDM Server 108 to send and receive any changes to the contacts or group list, and updates the user interface of the handset 134 based on the notifications it receives from the XDM Server 108.
The client module provides the most important function of making and receiving PoC calls. To support PoC calls, the client module creates and maintains pre-established sessions with the PoC Server 112. The client module supports 1-1, Ad Hoc and Pre-Arranged PoC calls. The client module also supports sending and receiving Instant Personal Alerts (IPA).
3.4 WiFi Interworking Solutions
Smart phones these days seamlessly transition between WiFi networks 142 and wireless data networks 126 to provide data connectivity. However, most PoC Clients 136 lose access to the Servers 108, 110, 112, 114, 116, 118, 120 and 122 when there is a handover or transition between a wireless data network 126 and a WiFi networks 142. As a result, PoC Service may be lost, when a handset 134 attempts to connect via a WiFi network 142 instead of a wireless data network 126, and PoC call sessions may be interrupted. The present invention provides a WiFi interworking solution, which results in seamless transitions for a handset 134 and PoC Client 136 between a wireless data network 126 and a WiFi network 142.
In the present invention, the PoC Client 136 handles the transitions between a wireless data network 126 and a WiFi network 142 by recognizing the type of network connectivity being used by the handset 134, and intelligently adapting, for the chosen network 126 or 144, the proper mechanisms for communication with the Servers 108, 110, 112, 114, 116, 118, 120, 122, 140 and 146.
In one embodiment, when an idle handover occurs between the wireless data network 126 and a WiFi network 142 (i.e., no PoC call session is in progress), the transition will be transparent to the user. Specifically, no indication of the transition may be displayed on the handset 134 while the PoC Client 136 is in the background, but the handset 134 may indicate the transition while PoC Client 136 is in foreground.
In another embodiment, when an in-call handover occurs between the wireless data network 126 and a WiFi network 142 (i.e., a PoC call session is in progress), specific actions may be taken to preserve the PoC call session, which may involve suspending the PoC call session while the in-call handover is taking place and then resuming the PoC call session when the in-call handover completes. The description of
When an in-call handover occurs between the wireless data network 126 and WiFi network 142 (i.e., a PoC call session is in progress), the handset 134 may or may not indicate the transition while PoC Client 136 is in foreground or background. In addition, control of the floor may or may not be revoked (locally, on the handset 134) and floor control may or may not be blocked during transition itself (e.g., for 6-12 seconds). Moreover, participation in the PoC call session may or may not be suspended for the handset 134 and PoC Client 136 in transition, while other (non-transitioning) participants in the PoC call may or may not continue with the session (for both private and group PoC calls). When the in-call handover between the wireless data network 126 and WiFi network 142 is completed, the suspended PoC Client 136 may automatically reconnect to the PoC call and continues the session.
In yet another embodiment, when an in-call handover occurs between the wireless data network 126 and WiFi network 142 (i.e., a PoC call session is in progress), the transition may or may not be transparent to the other (non-transitioning) participants of the PoC call. Specifically, the handsets 134 and PoC Clients 136 of the other (non-transitioning) participants of the PoC call session may receive a “Suspended” indication followed by a “Resumed” indication for the transitioning handset 134 and PoC Client 136 during the pendency of the transition. These indications may or may not be made both visual as well as audible to the other (non-transitioning) participants of the PoC call. In addition, control of the floor may or may not be revoked and floor control may or may not be blocked to the other (non-transitioning) participants of the PoC call session during the transition itself. The suspended PoC Clients 136 of the other (non-transitioning) participants of the PoC call session may automatically resume the PoC call session after the transitioning handset 134 and PoC Client 136 reconnect to the PoC call session when the in-call handover between the wireless data network 126 and WiFi network 142 is completed.
3.5 Call Flow Diagrams
3.5.1 1-1 PoC Calls
The messages are described below:
1. The caller's PoC Client 136 initiates a 1-1 PoC call on the pre-established session dialog by sending a SIP REFER request to its PoC Server 112. Since the call is initiated on an existing SIP dialog, the PoC Client 136 specifies the called party's URI in the SIP Refer-To header. The PoC Server 112 checks whether the call origination is authorized and accepts the request.
2. The PoC Server 112 finds that the called party is homed on a different PoC Server 112 and initiates a SIP INVITE dialog with the remote PoC Server 112. The caller's home PoC Server 112 allocates a new set of media ports for this purpose and informs the Media Server 114 of the same. The remote PoC Server 112 acknowledges the request to stop SIP retransmissions.
3. The remote PoC Server 112 (i.e., the called party's home PoC Server 112) checks whether the called party is authorized to receive the call, finds that the PoC Client 136 is in auto-answer mode and accepts the call. It allocates a new set of media ports for this INVITE dialog and informs its Media Server 114 of the same. The caller's home PoC Server 112 receives the SIP “200 Ok” response and sends a SIP ACK request to complete the transaction.
4. Upon successful SIP dialog setup, the originating/controlling PoC Server 112 sends MBCP Connect messages to both calling and called parties, and to connect the media ports related to the pre-established session dialog to that of the inter-server SIP INVITE dialog.
5. The calling party's Media Server 114 sends a MBCP Connect message to the calling party's PoC Client 136. This indicates to the calling party that the called party has accepted the call. Similarly, the called party's Media Server 114 sends a MBCP Connect message to the called party. This message is the first indication to the called party regarding the incoming call and includes both caller and PoC session information. Since the PoC Client 136 of the called party is setup in auto-answer mode, the call is already accepted.
6. For 1-1 PoC calls, the calling party's home PoC Server 112 assumes the Controlling PoC Function. After sending the MBCP Connect message to the calling party, the PoC Server 112 instructs the Media Server 114 to send appropriate floor control requests to the calling and called parties.
7. The Media Server 114 directly sends a MBCP Floor Granted message to the calling party, since the Media Server 114 is associated with the home PoC Server 112 of the caller, and this is where the media ports for the pre-established session dialog were set up. Note that this MBCP message may not be sent in the case where the caller had requested an implicit floor grant at the time of setting up the pre-established session.
8. The Media Server 114 sends a MBCP Floor Taken message to the called party through the called party's home Media Server 114. The MBCP messages between the two Media Servers 114 use the media ports allocated for the inter-server SIP INVITE dialog, while the MBCP messages are sent to the called party's PoC Client 136 using the media ports allocated for the pre-established session.
3.5.2 Ad Hoc PoC Calls
The messages are described below:
1. The PoC Client 136 initiates an Ad Hoc PoC call using the pre-established session by sending a SIP REFER request. The list of called parties is included in the message body of the SIP REFER request.
2. Since the calling and called parties are homed on the same PoC Server 112 and all of them use pre-established sessions in auto-answer mode, the PoC Server 112 authorizes the call origination and termination attempts and instructs the Media Server 114 to send MBCP Connect messages to the PoC Clients 136. It also specifies which party should be connected in which mode, e.g., whether as talker (calling party) or listener (called parties).
3. The Media Server 114 sends a MBCP Connect message to the calling party, followed by a MBCP Floor Granted message. The MBCP Floor Granted message is optional depending on whether the calling party had requested for implicit floor grant at the time of setting up the pre-established session.
4. The Media Server 114 then sends MBCP Connect and MBCP Floor Taken messages to the called parties. The first indication of an incoming call for the called parties is when they receive the MBCP Connect message with both caller and PoC session details. Since the PoC Clients 136 are set up in auto-answer mode, the calls are already accepted, and the PoC Clients 136 start receiving voice RTP packets when the caller starts speaking (RTP packets not shown in the message flow).
3.5.3 Pre-Arranged PoC Calls
The messages are described below:
1. The PoC Client 136 initiates a Pre-Arranged PoC call using the pre-established session by sending a SIP REFER request that specifies the PoC group URI in the SIP Refer-To header. The SIP REFER request is sent to the caller's home PoC Server 112, and the PoC Server 112 checks whether the caller is authorized to make this PoC call and then accepts the request.
2. The PoC Server 112 finds that the PoC group is homed on a different PoC Server 112 (the group owner's home PoC Server 112). It then allocates a new set of media ports and creates and sends a SIP INVITE request to the remote PoC Server 112 with the request URI set to the PoC group URI. The PoC Server 112 then informs the Media Server 114 of these media ports. The remote PoC Server 112 acknowledges the SIP INVITE request to stop retransmissions.
3. The remote PoC Server 112 (group home PoC Server 112) checks the validity of the group URI and checks whether the caller is allowed to initiate the call, as well as whether at least one member is able to receive the call. Then, it allocates a new set of media ports for the inter-server SIP INVITE dialog and sends a SIP “200 Ok” response to the caller's home PoC Server 112. The caller's home PoC Server 112 sends a SIP ACK request to complete the SIP transaction.
4. When the inter-server SIP INVITE dialog is successfully set up, the caller's home PoC Server 112 connects the caller-side inter-server media ports to the caller's pre-established session media ports.
5. At the same time, the group home PoC Server 112 instructs the Media Server 114 to connect the calling party and each of the called parties and join them into the conference, along with the group-home-side inter-server media ports. The Media Server 114 sends MBCP Connect messages to the calling party and each of the called parties and includes both caller and PoC session details. This message also includes the PoC group URI to provide additional context for the call. Since the PoC Clients 136 are set up in auto-answer mode, the MBCP Connect message will be the first indication of the incoming call for called parties. The call itself is already accepted and the PoC Client 136 will start receiving the voice RTP packets when the caller starts speaking
6. The group home PoC Server 112 assumes the role of Controlling PoC Function as described above and controls the floor by sending a MBCP Floor Granted message to the caller and MBCP Taken messages to each of the called parties.
3.5.4 Floor Control
MBCP messages are used by the PoC Client 136 and PoC Server 112 to exchange floor control messages within a PoC session. A MBCP Connect message is used for terminating an incoming PoC session to an invited party when the invited party has auto-answer enabled. This is also used for connecting the calling party to the call when at least one of the called parties accepts or auto-answers the call. Similarly, a MBCP Disconnect message is used for disconnecting the calling and called parties.
In this message flow, the first few messages show the MBCP Connect and associated intra-server messages that are used for joining the participants in the call, as well as the initial floor assignment. The direction of the RTP packets show whose voice packets get replicated to the other participants. The rest of the message flow show a floor release request from the current talker, a floor idle indication to all the participants, and subsequent floor request and grant for another participant in the call.
The messages are described below:
1. This set of messages is for a 1-1 PoC call to between subscribers A and B using a pre-established session (SIP signaling messages are not shown in the figure). The two parties are connected into the PoC session using MBCP Connect messages and an initial set of floor control messages are sent to the PoC Clients 136 as described in the 1-1 PoC session initiation scenario described above.
2. Since the floor is initially granted to the calling party, the voice RTP packets from subscriber A are sent to subscriber B by the Media Server 114. Although the individual call legs are established in full-duplex mode, the voice RTP packets originating from the listeners are dropped by the Media Server 114 to emulate half-duplex mode.
3. Subscriber A releases the floor after some time. The PoC Client 136 sends a MBCP Release message to the Media Server 114, which sends the indication to the PoC Server 112.
4. The PoC Server 112 instructs the Media Server 114 to set the floor as idle and notify all parties in the call by sending a MBCP Idle message to the PoC Clients 136.
5. Subscriber B requests for floor by sending a MBCP Request message to the Media Server 114. The Media Server 114 forwards the request to the PoC Server 112.
6. The PoC Server 112 grants the floor to subscriber B and instructs the Media Server 114 to send appropriate MBCP messages to all parties in the call. The Media Server 114 sends a MBCP Granted message to subscriber B's PoC Client 136 and a MBCP Taken message to subscriber A's PoC Client 136.
7. Based on the current floor owner, the Media Server 114 starts forwarding voice RTP packets from subscriber B to subscriber A, while dropping all RTP packets from subscriber A.
3.5.5 In-Call Transition (wireless data network to WiFi network)
The messages are described below:
1. The user at handset 134 “A” launches the PoC Client 136 and browses through the contact list to make a PoC call. The handset 134 is currently connected to wireless data network 126.
2. The caller's PoC Client 136 initiates a 1-1 PoC call on a pre-established session dialog by sending a SIP REFER request to its PoC Server 112. Since the call is initiated on an existing SIP dialog, the PoC Client 136 specifies the called party's URI in the SIP Refer-To header. The PoC Server 112 checks whether the call origination is authorized and accepts the request.
The PoC Server 112 finds that the called party is homed on a different PoC Server 112 and initiates a SIP INVITE dialog with the remote PoC Server 112. The caller's home PoC Server 112 allocates a new set of media ports for this purpose and informs the Media Server 114 of the same. The remote PoC Server 112 acknowledges the request to stop SIP retransmissions.
The remote PoC Server 112 (i.e., the called party's home PoC Server 112) checks whether the called party is authorized to receive the call, finds that the PoC Client 136 is in auto-answer mode and accepts the call. It allocates a new set of media ports for this INVITE dialog and informs its Media Server 114 of the same. The caller's home PoC Server 112 receives the SIP “200 Ok” response and sends a SIP ACK request to complete the transaction.
Upon successful SIP dialog setup, the originating/controlling PoC Server 112 sends MBCP Connect messages to both calling and called parties, and to connect the media ports related to the pre-established session dialog to that of the inter-server SIP INVITE dialog.
The calling party's Media Server 114 sends a MBCP Connect message to the calling party's PoC Client 136. This indicates to the calling party that the called party has accepted the call. Similarly, the called party's Media Server 114 sends a MBCP Connect message to the called party. This message is the first indication to the called party regarding the incoming call and includes both caller and PoC session information. Since the PoC Client 136 of the called party is setup in auto-answer mode, the call is already accepted.
For 1-1 PoC calls, the calling party's home PoC Server 112 assumes the Controlling PoC Function. After sending the MBCP Connect message to the calling party, the PoC Server 112 instructs the Media Server 114 to send appropriate floor control requests to the calling and called parties. Since the floor is initially granted to the calling party, the voice RTP packets from subscriber A are sent to subscriber B by the Media Server 114.
3. The handset 134 for user A moves into the coverage area of a known WiFi network 142 (known by its Service Set Identifier or SSID). This may cause the handset 134 to automatically connect to the WiFi network 142, or the user may manually cause the handset 134 to connect to the WiFi network 142, thereby initiating a transition from the wireless data network 126 to the WiFi network 142. During this transition, RTP packets are not received by the Media Server 114 from the transitioning PoC Client 136. This is detected by the Media Server 114 and it sends a “Suspended” indication to the other (non-transitioning) participants, as instructed by PoC Server 112. When the handset 134 for user A completes its transition and is connected to the WiFi network 142, it communicates via the RV Server 140. The PoC Client 136 resumes PoC service by first sending an RTCP APP transport change (UDP) indication to the Media Server 114 to inform the Media Server 114 that it will use TCP transport for all further floor changes. The PoC Client 136 then sends a first SIP REGISTER to its PoC Server 112, which is acknowledged, followed by a second SIP REGISTER to its PoC Server 112, which is also acknowledged, to update its contact IP address, by first dropping the previous IP address on the wireless data network 126 and then adding the new IP address on the WiFi network 142. Based on these messages, the Media Server 114 sends a “Resumed” indication to the other (non-transitioning) participants. Thereafter, the Media Server 114 sends appropriate floor control requests to the calling and called parties, and assuming that floor control is granted to the calling party (although it could be granted to one of the called parties), the voice RTP packets from subscriber A are sent to subscriber B by the Media Server 114.
3.5.6 in-Call Transition (WiFi Network to Wireless Data Network)
The messages are described below:
1. The user at handset 134 “A” launches the PoC Client 136 and browses through the contact list to make a PoC call. The handset 134 is currently connected to WiFi network 142.
2. The caller's PoC Client 136 initiates a 1-1 PoC call on a pre-established session dialog by sending a SIP REFER request to its PoC Server 112. Since the call is initiated on an existing SIP dialog, the PoC Client 136 specifies the called party's URI in the SIP Refer-To header. The PoC Server 112 checks whether the call origination is authorized and accepts the request.
The PoC Server 112 finds that the called party is homed on a different PoC Server 112 and initiates a SIP INVITE dialog with the remote PoC Server 112. The caller's home PoC Server 112 allocates a new set of media ports for this purpose and informs the Media Server 114 of the same. The remote PoC Server 112 acknowledges the request to stop SIP retransmissions.
The remote PoC Server 112 (i.e., the called party's home PoC Server 112) checks whether the called party is authorized to receive the call, finds that the PoC Client 136 is in auto-answer mode and accepts the call. It allocates a new set of media ports for this INVITE dialog and informs its Media Server 114 of the same. The caller's home PoC Server 112 receives the SIP “200 Ok” response and sends a SIP ACK request to complete the transaction.
Upon successful SIP dialog setup, the originating/controlling PoC Server 112 sends MBCP Connect messages to both calling and called parties, and to connect the media ports related to the pre-established session dialog to that of the inter-server SIP INVITE dialog.
The calling party's Media Server 114 sends a MBCP Connect message to the calling party's PoC Client 136. This indicates to the calling party that the called party has accepted the call. Similarly, the called party's Media Server 114 sends a MBCP Connect message to the called party. This message is the first indication to the called party regarding the incoming call and includes both caller and PoC session information. Since the PoC Client 136 of the called party is setup in auto-answer mode, the call is already accepted.
For 1-1 PoC calls, the calling party's home PoC Server 112 assumes the Controlling PoC Function. After sending the MBCP Connect message to the calling party, the PoC Server 112 instructs the Media Server 114 to send appropriate floor control requests to the calling and called parties. Since the floor is initially granted to the calling party, the voice RTP packets from subscriber A are sent to subscriber B by the Media Server 114.
3. The handset 134 for user A moves into the coverage area of the wireless data network 126. This may cause the handset 134 to automatically connect to the wireless data network 126, or the user may manually cause the handset 134 to connect to the wireless data network 126, thereby initiating a transition from the WiFi network 142 to wireless data network 126. During this transition, RTP packets are not received by the Media Server 114 from the transitioning PoC Client 136. This is detected by the Media Server 114 and it sends a “Suspended” indication to the other (non-transitioning) participants, as instructed by PoC Server 112. When the handset 134 for user A completes its transition and is connected to the wireless data network 1264, the PoC Client 136 resumes PoC service by first sending an RTCP APP transport change (UDP) indication to the Media Server 114 to inform the Media Server 114 that it will use UDP transport for all further floor changes. The PoC Client 136 then sends a first SIP REGISTER to its PoC Server 112, which is acknowledged, followed by a second SIP REGISTER to its PoC Server 112, which is also acknowledged, to update its contact IP address, by first dropping the previous IP address on the WiFi network 142 and then adding the new IP address on the wireless data network 126. Based on these messages, the Media Server 114 sends a “Resumed” indication to the other (non-transitioning) participants. Thereafter, the Media Server 114 sends appropriate floor control requests to the calling and called parties, and assuming that floor control is granted to the calling party (although it could be granted to one of the called parties), the voice RTP packets from subscriber A are sent to subscriber B by the Media Server 114.
3.5.7 No in-Call Transition (Defer Handover Until the Call Finishes)
In another embodiment, the handover may be deferred until the in-progress PoC call session is completed. In other words, the PoC Client 136 is configured such that no handover occurs during a PoC call. Instead, a handover would only occur once the PoC call is completed, and the handover would be performed in Idle mode, as described above.
The foregoing description of the preferred embodiment of the invention has been presented for the purposes of illustration and description. It is not intended to be exhaustive or to limit the invention to the precise form disclosed. Many modifications and variations are possible in light of the above teaching. It is intended that the scope of the invention be limited not with this detailed description, but rather by the claims appended hereto.
This application is a continuation under 35 U.S.C. Section 120 of the following co-pending and commonly-assigned patent application: U.S. Utility application Ser. No. 13/757,520, filed Feb. 1, 2013, by Krishnakant M. Patel, Harisha Mahabaleshwara Negalaguli, Brahmananda R. Vempati, Shiva Koteshwara Kiran Cheedella, Arun Velayudhan, Raajeev Kuppa, Gorachand Kundu, Ravi Ganesh Ramamoorthy, Ramu Kandula, Ravi Ayyasamy, and Ravi Shankar Kumar, entitled “WiFi INTERWORKING SOLUTIONS FOR PUSH-TO-TALK OVER CELLULAR (PoC),” attorneys' docket number 154.48-US-U1; which application claims the benefit under 35 U.S.C. Section 119(e) of the following co-pending and commonly-assigned patent application: U.S. Provisional Application Ser. No. 61/593,485, filed Feb. 1, 2012, by Krishnakant M. Patel, Harisha Mahabaleshwara Negalaguli, Brahmananda R. Vempati, Shiva Koteshwara Kiran Cheedella, Arun Velayudhan, Raajeev Kuppa, and Gorachand Kundu, entitled “WiFi INTERWORKING SOLUTIONS FOR PUSH-TO-TALK OVER CELLULAR (PoC) IN THE OPEN MOBILE ALLIANCE (OMA) STANDARD,” attorneys' docket number 154.48-US-P1; both of which applications are incorporated by reference herein. This application is related to the following commonly-assigned patent applications: U.S. Utility application Ser. No. 10/515,556, filed Nov. 23, 2004, by Gorachand Kundu, Ravi Ayyasamy and Krishnakant Patel, entitled “DISPATCH SERVICE ARCHITECTURE FRAMEWORK,” attorney docket number G&C 154.4-US-WO, now U.S. Pat. No. 7,787,896, issued Aug. 31, 2010, which application claims the benefit under 35 U.S.C. Section 365 of P.C.T. International Application Serial Number PCT/US03/16386 (154.4-WO-U1), which application claims the benefit under 35 U.S.C. Section 119(e) of U.S. Provisional Application Ser. Nos. 60/382,981 (154.3-US-P1), 60/383,179 (154.4-US-P1) and 60/407,168 (154.5-US-P1); U.S. Utility application Ser. No. 10/564,903, filed Jan. 17, 2006, by F. Craig Farrill, Bruce D. Lawler and Krishnakant M. Patel, entitled “PREMIUM VOICE SERVICES FOR WIRELESS COMMUNICATIONS SYSTEMS,” attorney docket number G&C 154.7-US-WO, which application claims the benefit under 35 U.S.C. Section 365 of P.C.T. International Application Serial Number PCT/US04/23038 (154.7-WO-U1), which application claims the benefit under 35 U.S.C. Section 119(e) of U.S. Provisional Application Ser. Nos. 60/488,638 (154.7-US-P1), 60/492,650 (154.8-US-P1) and 60/576,094 (154.14-US-P1) and which application is a continuation-in-part and claims the benefit under 35 U.S.C. Sections 119, 120 and/or 365 of P.C.T. International Application Serial Number PCT/US03/16386 (154.4-WO-U1); U.S. Utility application Ser. No. 11/126,587, filed May 11, 2005, by Ravi Ayyasamy and Krishnakant M. Patel, entitled “ARCHITECTURE, CLIENT SPECIFICATION AND APPLICATION PROGRAMMING INTERFACE (API) FOR SUPPORTING ADVANCED VOICE SERVICES (AVS) INCLUDING PUSH TO TALK ON WIRELESS HANDSETS AND NETWORKS,” attorney docket number 154.9-US-U1, now U.S. Pat. No. 7,738,892, issued Jun. 15, 2010, which application claims the benefit under 35 U.S.C. Section 119(e) of U.S. Provisional Application Ser. Nos. 60/569,953 (154.9-US-P1) and 60/579,309 (154.15-US-P1), and which application is a continuation-in-part and claims the benefit under 35 U.S.C. Sections 119, 120 and/or 365 of U.S. Utility application Ser. No. 10/515,556 (154.4-US-WO) and P.C.T. International Application Serial Number PCT/US04/23038 (154.7-WO-U1); U.S. Utility application Ser. No. 11/129,268, filed May 13, 2005, by Krishnakant M. Patel, Gorachand Kundu, Ravi Ayyasamy and Basem Ardah, entitled “ROAMING GATEWAY FOR SUPPORT OF ADVANCED VOICE SERVICES WHILE ROAMING IN WIRELESS COMMUNICATIONS SYSTEMS,” attorney docket number 154.10-US-U1, now U.S. Pat. No. 7,403,775, issued Jul. 22, 2008, which application claims the benefit under 35 U.S.C. Section 119(e) of U.S. Provisional Application Ser. No. 60/571,075 (154.10-US-P1), and which application is a continuation-in-part and claims the benefit under 35 U.S.C. Sections 119, 120 and/or 365 of U.S. Utility application Ser. No. 10/515,556 (154.4-US-WO) and P.C.T. International Application Serial Number PCT/US04/23038 (154.7-WO-U1); U.S. Utility application Ser. No. 11/134,883, filed May 23, 2005, by Krishnakant Patel, Vyankatesh V. Shanbhag, Ravi Ayyasamy, Stephen R. Horton and Shan-Jen Chiou, entitled “ADVANCED VOICE SERVICES ARCHITECTURE FRAMEWORK,” attorney docket number 154.11-US-U1, now U.S. Pat. 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Section 119(e) of U.S. Provisional Application Ser. No. 60/742,250 (154.23-US-P1); U.S. Utility application Ser. No. 11/740,805, filed Apr. 26, 2007, by Krishnakant M. Patel, Giridhar K. Boray, Ravi Ayyasamy, and Gorachand Kundu, entitled “ADVANCED FEATURES ON A REAL-TIME EXCHANGE SYSTEM,” attorney docket number 154.26-US-U1, now U.S. Pat. No. 7,853,279, issued Dec. 14, 2010, which application claims the benefit under 35 U.S.C. Section 119(e) of U.S. Provisional Application Ser. No. 60/795,090 (154.26-US-P1); U.S. Utility application Ser. No. 11/891,127, filed Aug. 9, 2007, by Krishnakant M. Patel, Deepankar Biswas, Sameer P. Dharangaonkar and Terakanambi Nanjanayaka Raja, entitled “EMERGENCY GROUP CALLING ACROSS MULTIPLE WIRELESS NETWORKS,” attorney docket number 154.27-US-U1, which application claims the benefit under 35 U.S.C. Section 119(e) of U.S. Provisional Application Ser. No. 60/836,521 (154.27-US-P1); U.S. Utility application Ser. No. 12/259,102, filed on Oct. 27, 2008, by Krishnakant M. Patel, Gorachand Kundu, and Ravi Ayyasamy, entitled “CONNECTED PORTFOLIO SERVICES FOR A WIRELESS COMMUNICATIONS NETWORK,” attorneys' docket number 154.32-US-U1, which application claims the benefit under 35 U.S.C. Section 119(e) of U.S. Provisional Application Ser. Nos. 60/982,650 (154.32-US-P1) and 61/023,042 (154.32-US-P2); U.S. Utility application Ser. No. 12/359,861, filed on Jan. 26, 2009, by Bruce D. Lawler, Krishnakant M. Patel, Ravi Ayyasamy, Harisha Mahabaleshwara Negalaguli, Binu Kaiparambil, Shiva Cheedella, Brahmananda R. Vempati, Ravi Shankar Kumar, and Avrind Shanbhag, entitled “CONVERGED MOBILE-WEB COMMUNICATIONS SOLUTION,” attorneys' docket number 154.33-US-U1, now U.S. Pat. No. 8,676,189, issued Mar. 18, 2014, which application claims the benefit under 35 U.S.C. Section 119(e) of U.S. Provisional Application Ser. No. 61/023,332 (154.33-US-P1); U.S. Utility application Ser. No. 12/582,601, filed Oct. 20, 2009, by Krishnakant M. Patel, Ravi Ayyasamy, Gorachand Kundu, Basem A. Ardah, Anand Narayanan, Brahmananda R. Vempati, and Pratap Chandana, entitled “HYBRID PUSH-TO-TALK FOR MOBILE PHONE NETWORKS,” attorney docket number 154.36-US-U1, now U.S. Pat. No. 8,958,348, issued Feb. 17, 2016, which application claims the benefit under 35 U.S.C. Section 119(e) of U.S. Provisional Application Ser. No. 61/106,689 (154.36-US-P1); U.S. Utility application Ser. No. 12/781,566, filed on May 17, 2010, by Bruce D. Lawler, Krishnakant M. Patel, Ravi Ayyasamy, Harisha Mahabaleshwara Negalaguli, Binu Kaiparambil, Shiva K.K. Cheedella, Brahmananda R. Vempati, and Ravi Shankar Kumar, entitled “CONVERGED MOBILE-WEB COMMUNICATIONS SOLUTION,” attorneys' docket number 154.38-US-I1, now U.S. Pat. No. 8,670,760, issued Mar. 11, 2014, which application is a continuation-in-part and claims the benefit under 35 U.S.C. Sections 119, 120 and/or 365 of U.S. Utility application Ser. No. 12/582,601 (154.36-US-U1); U.S. Utility application Ser. No. 12/750,175, filed on Mar. 30, 2010, by Bruce D. Lawler, Krishnakant M. Patel, Ravi Ayyasamy, Harisha Mahabaleshwara Negalaguli, Basem A. Ardah, Gorachund Kundu, Ramu Kandula, Brahmananda R. Vempati, Ravi Shankar Kumar, Chetal M. Patel, and Shiva K.K. Cheedella, entitled “ENHANCED GROUP CALLING FEATURES FOR CONNECTED PORTFOLIO SERVICES IN A WIRELESS COMMUNICATIONS NETWORK,” attorneys' docket number 154.39-US-U1, now U.S. Pat. No. 8,498,660, issued Jul. 30, 2013, which application claims the benefit under 35 U.S.C. Section 119(e) of U.S. Provisional Application Ser. Nos. 61/164,754 (154.39-US-P1) and 61/172,129 (154.39-US-P2); U.S. Utility application Ser. No. 12/961,419, filed Dec. 6, 2010, by Ravi Ayyasamy, Bruce D. Lawler, Brahmananda R. Vempati, Gorachand Kundu and Krishnakant M. Patel, entitled “COMMUNITY GROUP CLIENT AND COMMUNITY AUTO DISCOVERY SOLUTIONS IN A WIRELESS COMMUNICATIONS NETWORK,” attorneys' docket number 154.40-US-U1, which application claims the benefit under 35 U.S.C. Section 119(e) of U.S. Provisional Application Ser. No. 61/266,896 (154.40-US-P1); U.S. Utility application Ser. No. 13/039,635, filed on Mar. 3, 2011, by Narasimha Raju Nagubhai, Ravi Shankar Kumar, Krishnakant M. Patel, and Ravi Ayyasamy, entitled “PREPAID BILLING SOLUTIONS FOR PUSH-TO-TALK IN A WIRELESS COMMUNICATIONS NETWORK,” attorneys' docket number 154.41-US-U1, now U.S. Pat. No. 8,369,829, issued Feb. 5, 2013, which application claims the benefit under 35 U.S.C. Section 119(e) of U.S. Provisional Application Ser. No. 61/310,245 (154.41-US-P1); U.S. Utility application Ser. No. 13/093,542, filed Apr. 25, 2011, by Brahmananda R. Vempati, Krishnakant M. Patel, Pratap Chandana, Anand Narayanan, Ravi Ayyasamy, Bruce D. Lawler, Basem A. Ardah, Ramu Kandula, Gorachand Kundu, Ravi Shankar Kumar, and Bibhudatta Biswal, and entitled “PREDICTIVE WAKEUP FOR PUSH-TO-TALK-OVER-CELLULAR (POC) CALL SETUP OPTIMIZATIONS,” attorneys' docket number 154.42-US-U1, now U.S. Pat. No. 8,478,261, issued Jul. 2, 2013, which application claims the benefit under 35 U.S.C. Section 119(e) of U.S. Provisional Application Ser. No. 61/347,217 (154.42-US-P1); and U.S. Utility application Ser. No. 13/710,683, filed Dec. 11, 2012, by Ravi Ayyasamy, Gorachand Kundu, Krishnakant M. Patel, Brahmananda R. Vempati, Harisha M. Negalaguli, Shiva K. K. Cheedella, Basem A. Ardah, Ravi Shankar Kumar, Ramu Kandula, Arun Velayudhan, Shibu Narendranathan, Bharatram Setti, Anand Narayanan, and Pratap Chandana, entitled “PUSH-TO-TALK-OVER-CELLULAR (PoC),” attorneys' docket number 154.43-US-U1, which application claims the benefit under 35 U.S.C. Section 119(e) of U.S. Provisional Application Ser. No. 61/570,694 (154.43-US-P2; all of which applications are incorporated by reference herein.
Number | Date | Country | |
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61593485 | Feb 2012 | US |
Number | Date | Country | |
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Parent | 13757520 | Feb 2013 | US |
Child | 14738459 | US |