1. Field of the Invention:
This invention relates to communications. Specifically, the invention relates to optimizing a network based on the user application operating on the network.
2. Description of the Prior Art:
Conventional communications networks often include both circuit-switched technologies and packet-switched technologies. Since circuit-switched networks were implemented first, many network applications are implemented to operate on circuit-switched networks and are not optimized for packet-switched networks. However, a wide variety of new applications are being implemented to take advantage of the efficiencies that can be gained when using packet-switched networks.
In addition to circuit-switched networks and packet-switched networks, wireless networks are also widely deployed. The wireless networks are often based on wireless network standards that define the interfaces between different components in the networks and the various packet formats that are used in the interfaces. For example, Second-Generation Wireless Network (2G) standards and Third-Generation Wireless Network (3G) standards are currently being deployed. Some of the more recent standards provide for multimedia traffic, such as voice and data traffic across these networks. Since these networks are also integrated into conventional circuit-switched and packet-switched networks, specialized multimedia applications that are driven by wireless technologies are now deployed across circuit-switched and packet-switched networks. For example, standards-based protocols, such as H.323 and Session Initiation Protocol (SIP), are currently being deployed to integrate multimedia functionality across wireless networks, circuit-switched networks, and packet-switched networks.
Given the need for ubiquitous communications, methods have developed for providing applications across wireless, packet-switched, and circuit-switched networks. However, depending on the type of network that the technology was initially deployed on, the technology may be optimized for one network, but may not be optimized for other types of network. In addition, very little network optimization is performed based on user applications. Instead, most optimization is performed based on the implementing technology.
Thus, there is a need for a method and apparatus for optimizing a network based on the technology. Further, there is a need to optimize a network based on user applications.
A method and apparatus is presented for optimizing a packet-switched network based on user applications, such as Push-To-Talk (PTT), Voice-over-IP (VoIP), etc.
Currently, to establish a data call, a single A10 interface is established between a Packet Control Function (PCF of a base station (BS and a Packet Data Serving Node (PDSN) to transport user payloads, such as Internet Protocol (IP) packets. The A10 interface is established set up by sending signaling messages between the Packet Communication Facility (PCF) and a PDSN. The interface used for transporting the control plane (i.e., the signaling messages) between the PCF and the PDSN is known as the A11 interface. The A10 interface, the A11 interface, and other aspects of the present invention are defined in Interoperability Specification (IOS) for cdma2000 Access Network Interfaces Part 7—A10 and A11 Interfaces, 3G-IOSv4.3, 3GPP2 A.S0017-A, Version 2.0.1, http://www.3gpp2.org/Public_html/specs/A.S0017-A_v2.0.1 121903.pdf, July 2003, which is herein incorporated by reference.
In accordance with the teachings of the present invention, methods are presented to differentiate the content of the A10 interface (i.e., between the PCF and PDSN) based on the packet application to be transported across this interface. In one embodiment, the contents of the packet applications are differentiated as signaling packets and bearer packets. For example, real-time user applications (i.e., such as VoIP and PTT) may not require retransmission services provided by protocols, such as the Radio Link Protocol (RLP) as proposed by CDMA standards (i.e., such as TIA/EIA/IS-707). Taking away the RLP, however, may hinder the guaranteed delivery aspect of signaling messages and may significantly degrade the quality of the service. To ensure that the signaling packets are not lost, an A10 interface, implemented in accordance with the teachings of the present invention, separates the signaling packets so that they can be treated with higher priority than that of the bearer packets. Since a very small portion of the call/session holding time consists of signaling packets (i.e., such as SIP message for PTT), the chances of degrading the media quality (i.e., such as VoIP traffic for PTT) is fairly insignificant by treating the signaling packets with higher priority.
In one embodiment, the content of the A10 interface is differentiated by adding an extension in the A11-Registration Request message that is sent from the PCF to the PDSN informing the PDSN of the specialized application (i.e., such as PTT). In one embodiment, a Vendor Specific Extension (VSE) as specified in Dommety, G. and Leung, K. RFC 3025, Mobile IP Vendor/Organization-Specific Extensions, IETF, http://rfc.sunsite.dk/rfc/rfc3025.html, February 2001, which is incorporated herein by reference, can be used to add the extension to A11-Registration Request message.
A method for transporting both signaling messages and user payloads across a single A10 interface is presented. For example, a single A10 interface may be implemented as a channel for a Session Initiated Protocol (SIP)-based signaling messages for PTT as well as a channel for VoIP-based voice traffic for PTT. In accordance with the teachings of the present invention, this is accomplished by adding a flag (i.e., typically one toggle bit) in a Generic Routing Encapsulation (GRE) header to differentiate the specific application signaling (i.e., such as PTT SIP messages) from the user payload (i.e., such as the PTT VoIP traffic). The GRE is defined in Farinacci, et al., RFC 2784, Generic Routing Encapsulation (GRE), Internet Engineering Task Force, March 2000, which is herein incorporated by reference http://www.ietf.org/rfc/rfc2784.txt?number=2784).
A method is presented that uses Radio Link Protocol (RLP) to send application specific messages (i.e., such as PTT) between a Mobile Station (MS) and a BS. In one embodiment, PTT signaling messages (i.e., such as SIP messages for floor control) are sent as PTT Block Of Bits (PTT BLOB) between an MS and BS. The MS or the BS discovers that the user is running a specific application (i.e., such as PTT) and then sends signaling messages over the RLP (i.e., such as PTT BLOB) with a specific flag to designate these bits as a specialized message.
A method is presented that uses Short Data Burst (SDB) for delivering application specific signaling messages (i.e., such as SIP messages for PTT) to an MS while they are dormant. This is performed when the PCF receives a signaling message destined for a dormant MS and the PCF discovers that the MS is running a specific application (i.e., such as PTT) and decides to deliver the signaling message directly to the MS using the SDB feature. The SDB features are defined in Interoperability Specification (IOS) for High Rate Packet Data (HRPD) Access Network Interfaces 3 Revision 0, 3GPP2 A.S0008-0 v3. 0, http://www.3gpp2.org/Public_html/specs/A.S0008-0_v3.0. df, May 2003, which are herein incorporated by reference.
A method of operating a packet network, comprises the steps of processing a message in a standardized interface, the message including an indicia; and identifying a packet application in response to the indicia.
A method of operating a packet network, comprises the steps of communicating an A10 message including a generic routing encapsulation header; and identifying a type of message in response to the generic routing encapsulation header.
A method of identifying an application in a packet network, comprises the steps of identifying a user application; formulating a message including a flag, the flag identifying the user application; and communicating the message including the flag using a radio link protocol.
A method of operating a dormant MS, comprises the steps of receiving a signaling message; identifying a packet-based application in response to receiving the signaling message; and communicating the signaling message to a dormant MS using a short data burst.
A method of operating network, comprises the steps of receiving a reverse SDB from a dormant MS; and delivering the SDB to a PDSN using an A10 interface.
While the present invention is described herein with reference to illustrative embodiments for particular applications, it should be understood that the invention is not limited thereto. Those having ordinary skill in the art and access to the teachings provided herein will recognize additional modifications, applications, and embodiments within the scope thereof and additional fields in which the present invention would be of significant utility.
A new interface between a Base Station (BS) and a Packet Data Service Node (PDSN) also know as A10 interface in the Code Division Multiple Access (CDMA) standards, such as 3rd Generation Partnership Project (3GPP2), Telecommunications Industry Association (TIA), and Internet Engineering Task Force (IEET) is presented. During a data call, a single A10 interface is established to transport payload between the PCF of the BS and the PDSN. In accordance with the teachings of the present invention, several methods and network configurations are presented: 1) to differentiate the content of the A10 interface based on the packet application; 2) to transport both signaling messages and user payloads across the A10 interface; 3) to transport application specific messages between the MS and the BS using RLP; and 4) to deliver application specific messages to a dormant MS using SDB.
In one embodiment, a method of operating a packet network, comprises the steps of processing a message in a standardized interface, the message including an indicia that identifies a packet application. A variety of standardized interfaces that conform with the 3GPP2 project are presented and within the scope of the present invention. An indicia such as a special code placed in a message field (i.e., packet field) is implemented to identify packet applications. As such, specific types of applications may be distinguished and provided with specialized treatment. In accordance with the teachings of the present invention, packet applications include both signaling packets and payload packets. As such, using the methods and apparatus of the present invention, signaling packets and payload packets may be distinguished. In addition, packet applications include real-time packet applications that have time constraints to operate properly. Examples, of real-time packet applications include Push-to-Talk, Voice-over-IP, wireless internet messaging, real-time video, push-to-media, etc.
During operation of the network depicted in
During operation, at step 214, the MS 200 initiates a registration process for a specific packet-based application. At step 216, the PCF 208 is requested to setup an A10 interface between the PCF 208 and the PDSN 212. At step 218, the PCF 208 sends an A11-Registration message to the PDSN 212 indicating that this requested A10 interface will have different packet applications so that both signaling messages (i.e., such as SIP messages for PTT) and bearer plane (i.e., such as VoIP-based voice traffic for PTT) for serving this special user application (i.e., such as PTT). At step 220, the PCF 208 and the PDSN 212 set up a A10 interface for this special application (i.e., such as PTT) so that both control plane (i.e., such as SIP message for PTT) and the bearer plane (i.e., such as VoIP traffic for PTT) related to this application can be channeled through this A10 interface. As shown by 222, the MS 200 can now initiate the new packet-based application (i.e., such as PTT) across the wireless access network.
At step 414, the IP-based packet network 410 sends information packets (i.e., messages) associated with a specific packet-based application (i.e., such as PTT) toward an MS 400. The PDSN 412 has to perform internal processing and interrogate the contents of the packet in order to determine how to mark the packet in the GRE header. The PDSN 412 then includes a flag in the GRE header so that the PCF 408 can distinguish the signal plane (i.e., such as SIP messages for PTT) from the control plane (i.e., such as VoIP traffic for PTT). The information packets associated with a specific application (i.e., such as PTT) are then shipped to the PCF 408.
As shown by 416, the PCF 408 receives the information packets from the PDSN 412 that are associated with a specific packet-based application (i.e., such as PTT). The PCF 408 first looks at the flag in the GRE header (i.e., as inserted by the PDSN 412) to determine if the information packets are signaling packets (i.e., such as SIP messages for PTT) or bearer packets (i.e., such as VoIP traffic for PTT). The PCF 408 then separates the signaling packets from the bearer packets and sends them to the BS 402.
As shown by 418, the BS 402 receives the information packets associated with a specific packet-based application (i.e., such as PTT) from the PCF 408. The BS 402 first separates the signaling plane (i.e., such as SIP messages for PTT) and the bearer plane (i.e., such as VoIP traffic for PTT) and then forwards them to the MS 400.
In one embodiment, the application type 520 may be implemented as shown by the Table I:
A number of fields are shown in
During operation, a PDSN may perform the following actions upon receiving any of these messages (i.e., A11-Registration Request, A11-Registration Update, and A11-Session Update) implemented in accordance with the teachings for the present invention (i.e.,
1. upon receiving the A11-Registration Request message, the PDSN may set up the proposed A10 interface with the PCF;
2. upon receiving the A11-Registration Update message, the PDSN may update the necessary information to continue to maintain the proposed A10 interface with the PCF; and
upon receiving the A11-Session Update message, the PDSN may update the session associated with the propose A10 interface with the PCF.
The PDSN may create either an A10 interface as described in Interoperability Specification (IOS) for cdma2000 Access Network Interfaces Part 7—A10 and A11 Interfaces, 3G-IOSv4.3, 3GPP2 A.S0017-A, Version 2.0.1, http://www.3gpp2.org/Public_html/specs/A.S0017-A_v2.0.1—121903.pdf, July 2003, or may create an A10 interface as proposed by this invention using any combination of A10 Type and Application Type fields received in these messages.
In accordance with the teachings of the present invention, a special flag in the GRE header is presented as part of the A10 interface when information packets are transported between the PDSN and the PCF. It should be appreciated that any of the reserved bits of the GRE header (i.e., as describe in Interoperability Specification (IOS) for High Rate Packet Data (HRPD) Access Network Interfaces 3 Revision 0, 3GPP2 A.S0008-0 v3. 0, http://www.3gpp2.org/Public_html/specs/A.S0008-0_v3.0pdf, May 2003,) may be used to convey the payload type. For example, in one embodiment the flags may be implemented as follows:
At 712, the PDSN sends information packets associated with a specific packet-based application (i.e., such as PTT) to the PCF 708. The information packets are destined for an MS that is currently registered in the wireless access network (i.e.,
In
The A1 interface carries signaling information between the Call Control (CC) and Mobility Management (MM) functions of the MSC and the call control component of the BS (BSC). The A3 interface is used for inter-BS soft/softer handoff when a target BS is attached to the frame selection function within the source BS. The A3 interface carries coded user information (voice/data) and signaling information between the SDU function and the channel element component of the BS (BTS). This is a logical description of the endpoints of the A3 interface. The physical endpoints are beyond the scope of this specification. The A3 interface is composed of two parts: signaling and user traffic. The signaling information is carried across a separate logical channel from the user traffic channel and controls the allocation and use of channels for transporting user traffic.
The A7 interface carries signaling information between a source BS and a target BS. The A7 interface is used between the source BS and the target BS for inter-BS soft/softer handoff. The A8 interface carries user traffic between the BS and the PCF. The A8 interface is used to provide a path for user traffic between source BSC and PCF for packet data services. The A9 interface carries signaling information between the BS and the PCF. The A9 interface is used to provide a signaling connection between source BSC and PCF for packet data services. The A10 interface carries user traffic between the PCF and the PDSN. The A10 interface is used to provide a path for user traffic between a PCF and a PDSN for packet data services. The A11 interface carries signaling information between the PCF and the PDSN. This is a logical architecture that does not imply any particular physical implementation. The A11 interface is used to provide a signaling connection between a PCF and a PDSN for packet data services.
At step 802, the message including the indicia identifying the packet-based application is communicated. The message may be communicated from an MS, a BTS, a Call Processor (CP), a Routing Manager (RM), a Routing Agent (RA), a BSS, a BSC, an MSC, a PCF, an IP-based network, or a PDSN depending on the interface. In addition, the message may be communicated between networks. At step 804, the message is received. The message may be received in an MS, a BTS, a CP, a RM, a RA, a BSS, a BSC, an MSC, a PCF, an IP-based network, or a PDSN depending on the interface. In addition, the message may be received in one network from another network. A test is then made at the receiving point as stated at 806. The test is made to determine if the message includes the indicia. If the message does include the indicia, the message is given specialized treatment as stated at 808. Specialized treatment may involve performing additional processes, providing priority service, etc. If the message does not include the indicia, the message is not given specialized treatment as stated at 810.
While the present invention is described herein with reference to illustrative embodiments for particular applications, it should be understood that the invention is not limited thereto. Those having ordinary skill in the art and access to the teachings provided herein will recognize additional modifications, applications, and embodiments within the scope thereof and additional fields in which the present invention would be of significant utility.
It is, therefore, intended by the appended claims to cover any and all such applications, modifications, and embodiments within the scope of the present invention.
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/US05/05602 | 2/23/2005 | WO | 5/14/2007 |
Number | Date | Country | |
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60547297 | Feb 2004 | US |