Abstract:
A technique is provided for a direct data transfer session, including for multimedia content, between mobile devices without the need for using a separate multimedia server to store multimedia content. Direct data transfer sessions between mobile devices are established by transmitting necessary address information through page-based messaging services that utilize the underlying digital mobile network databases and services to resolve the identification and location of the mobile devices.

Description:
CROSS REFERENCE TO RELATED APPLICATIONS 
     This application is a continuation of U.S. patent application Ser. No. 12/832,576 filed Jul. 8, 2010, which is a continuation of U.S. patent application Ser. No. 11/042,620, filed Jan. 24, 2005, which is a continuation-in-part of U.S. patent application Ser. No. 10/817,994, filed Apr. 5, 2004, and a continuation-in-part of U.S. patent application Ser. No. 10/935,342, filed Sep. 7, 2004, which are all incorporated by reference herein. 
    
    
     FIELD OF THE INVENTION 
     The present invention relates generally to data transfer techniques for mobile devices, and more specifically, a technique to establish data transfer directly between mobile devices. 
     BACKGROUND OF THE INVENTION 
     Current multimedia messaging technologies for mobile devices depend upon a server that receives and prepares multimedia content to be retrieved by the recipient of the multimedia message. For example, the Multimedia Messaging Service (“MMS”) protocol utilizes a server known as a Multi Media Service Center (“MMSC”) to store multimedia content in preparation for a retrieval process initiated by the recipient. Specifically, under MMS, the initiating device initiates a data connection over TCP/IP and performs an HTTP POST of an MMS Encapsulation Format encoded multimedia message to the MMSC. The MMSC stores the multimedia message and makes it available as a dynamically generated URL link. The MMSC then generates a notification message containing the dynamically generated URL and sends the notification message to the recipient through WAP Push over the Short Message Service (“SMS”) protocol. When the recipient receives the MMS notification message, it initiates a data connection over TCP/IP and performs an HTTP request to retrieve the MMS message containing multimedia content from the MMSC through the dynamically generated URL. 
     The MMSC is used, in part, by the MMS protocol in order to provide a known address (e.g., a URL) that can be provided to the recipient in a text based format in order to initiate a data transfer transaction to retrieve the multimedia content. Without such a known address, the sender would be unable to transmit multimedia content to the recipient, since other pre-existing messaging technologies (e.g., SMS) only provide the capability to send limited text, and not multimedia content, directly to the recipient. As such, what is needed is a method to establish data transfer sessions directly between mobile devices, where such mobile devices are capable of directly communicating with other mobile devices through the underlying wireless technology, such that no separate multimedia server and separate retrieval notification message is needed to obtain data (e.g., multimedia content) other than text. 
     SUMMARY OF THE INVENTION 
     The present invention provides a method for establishing a direct data transfer session between mobile devices over a digital mobile network system that supports data packet-based communications. Under the present invention, no separate data server need be used to provide a known location from which a recipient retrieves data such as multimedia content. Instead, a mobile device initiating a data transfer opens a listening port defined by an underlying data packet based network protocol. The initiating mobile device sends an invitation message containing the network address, including the listening port, of the initiating device to a target mobile device through a page-mode messaging service (e.g., text based service) supported by the digital mobile network system. The initiating mobile device further utilizes and incorporates a unique identification number (e.g., telephone number, PIN number, etc.) associated with the target mobile device into the invitation message to locate and contact the target mobile device within the wireless mobile network. Once the initiating mobile device receives a response from the target mobile device at the listening port, the two mobile devices are able to establish a reliable virtual connection through the underlying data packet-based network protocol in order to transfer data directly between the two mobile devices. 
    
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
         FIG. 1  depicts a diagram of an environment for establishing a data transfer session in accordance with the present invention between a first mobile device and a second mobile device in a GSM mobile network system supporting GPRS as a data packet-based communications service, SMS as a text messaging service, and TCP/IP as an underlying data packet based network protocol. 
         FIG. 2  depicts a flow chart for establishing a data transfer session in accordance with the present invention. 
         FIG. 3  depicts a flow chart for a second embodiment for establishing a data transfer session in accordance with the present invention. 
     
    
    
     DETAILED DESCRIPTION OF THE INVENTION 
       FIG. 1  depicts one environment to deploy an embodiment of the present invention. As depicted, the underlying digital mobile network system in this environment is the Global System for Mobile communications (GSM)  100  standard. Under the GSM standard, each of the mobile devices  105  and  110  includes a Subscriber Information Module (SIM) card that contains unique identification information that enables the GSM system to locate the mobile devices within the network and route data to them. A current commercial example of a mobile device (e.g., smartphone, PDA, handheld, etc.) that might be used in  FIG. 1  could be Research In Motion&#39;s (RIM) BlackBerry handheld devices, which include a QWERTY keyboard to facilitate the typing of text. As depicted, a GSM architecture includes the following components: base transceiver stations (BTS)  115  and base station controllers (BSC) ( 120 A or  120 B) for managing the transmission of radio signals between the MSC (defined below) and the mobile devices, mobile service-switching centers (MSC) ( 125 A and  125 B) for performing the all switching functions and controlling calls to and from other telephone and data systems, a home location register (HLR)  130  for containing all the administrative, routing and location information of each subscriber registered in the network, visitor location registers (VLR) ( 135 A and  135 B) for containing selected administrative information about subscribers registered in one HLR who are roaming in a another HLR, and an equipment identity register (EIR) (not shown) for containing a list of all valid mobile equipment on the network). As depicted in  FIG. 1 , in one architecture of a GSM network, there may be exist one HLR while there may exist multiple MSCs (each with a related VLR) which each serves a different geographic area. The MSCs also provide the interface for the GSM network to more traditional voice networks  170  such as the PSTN. This underlying GSM architecture provides radio resources management (e.g., access, paging and handover procedures, etc.), mobility management (e.g., location updating, authentication and security, etc.), and communication management (e.g., call routing, etc.) in order to enable mobile devices in the GSM network to send and receive data through a variety of services, including the Short Message Service (SMS), an asynchronous bi-directional text messaging service for short alphanumeric messages (up to 160 bytes) that are transported from one mobile device to another mobile device in a store-and-forward fashion. 
     A GSM network within which the present invention may be deployed would also support a page-mode messaging service, such as SMS, that relies upon the underlying GSM mechanisms to resolve routing information in order to locate destination mobile devices. A GSM network supporting SMS text messaging may further include the following SMS specific components: a short message service center (SMSC) ( 140 A or  140 B) for storing and forwarding messages to and from one mobile device to another, an SMS Gateway-MSC (SMS GMSC) for receiving the short message from the SMSC ( 140 A or  140 B) and interrogating the destination mobile device&#39;s HLR  130  for routing information to determine the current location of the destination device to deliver the short message to the appropriate MSC ( 125 A or  125 B). The SMS GMSC is typically integrated with the SMSC  140 . In a typical transmission of an SMS text message from an originating mobile device  105  to a receiving mobile device  110 , (i) the text message is transmitted from the mobile  105  to the MSC  125 A, (ii) the MSC  125 A interrogates its VLR  135 A to verify that the message transfer does not violate any supplementary services or restrictions, (iii) the MSC  125 A sends the text message to the SMSC  140 A, (iv) the SMSC  140 A, through the SMS GMSC, interrogates the receiving mobile device&#39;s HLR  130  (by accessing the SS7 network) to receive routing information for the receiving mobile device  110 , (v) the SMSC sends the text message to the MSC  125 B servicing receiving mobile device  110 , (vi) the MSC  125 B retrieves subscriber information from the VLR  135 B, and (vii) the MSC  125 A transmits the text message to the receiving mobile device  110 . Similar to other transactions on the GSM network, SMS text messaging utilizes telephone numbers as identifying addresses for mobile devices and as such, utilizes the SS7 network signaling system through which cellular service providers share information from the HLR with other service providers. As depicted in  FIG. 1 , SS7 based signaling communication is represented by the broken lines. In contrast, the solid lines in  FIG. 1  represent data or voice based communications. 
     In addition to a page-mode messaging service such as SMS, a GSM network within which the present invention may be deployed would also support a data packet based communications service, such as the General Packet Radio Service (GPRS), that enables TCP/IP transmission protocol based communications between mobile devices within the network. As depicted in  FIG. 1 , a core GPRS network exists in parallel to the existing GSM core network. The BSC  120  may direct voice traffic through the MSC ( 125 A or  125 B) to the GSM network and data traffic through the Serving GPRS Support Note (SGSN) ( 145 A or  145 B) to the GPRS network. Such communication between the BSC ( 125 A or  125 B) and the SGSN ( 145 A or  145 B) may be, for example, based upon the IP network protocol communication  155 . As such, GPRS signaling and data traffic do not flow through the core GSM network. Instead, the core GSM network is used by GPRS only for table look-up in the HLR  130  and VLR ( 135 A or  135 B) to obtain routing, location and other subscriber information in order to handle user mobility. The SGSN ( 145 A or  145 B) serves as a “packet-switched MSC,” delivering data packets to mobile devices in its service area. The Gateway GPRS Support Note (GGSN) ( 150 A or  150 B) communicates with the SGSN ( 145 A or  145 B) through an IP based GPRS backbone  160  and serves as an interface to other external IP networks  165  such as the Internet and other mobile service providers&#39; GPRS services. 
     In order to provide direct data transfer capabilities between mobile devices, an initiating mobile device must have knowledge of the IP address (and possibly, a port) of the target device in order to establish a direct data transfer. Current mobile multimedia messaging solutions, such as MMS do not provide direct data transfer capabilities because the initiating mobile device is not able to obtain the receiving mobile device&#39;s IP address. In essence, servers such as the MMSC that are used in current multimedia messaging solutions serve as a forwarding agent between the two mobile devices that are unable to determine the other devices IP address. 
     In contrast, in accordance with the present invention, a multimedia server such as the MMSC can be eliminated on a mobile network environment such as that depicted on  FIG. 1 . Through the use of a page-mode messaging service, such as SMS, which transmits messages to mobile devices based upon their telephone numbers, an initiating mobile device can transmit its IP address (and a listening port) in an invitation message to a target mobile device through the target device&#39;s telephone number. Once the target device receives the invitation message, it is able to contact the initiating mobile device through the received IP address and the two devices can establish a reliable virtual connection, such as a TCP connection, for reliable data transfer session.  FIG. 2  depicts a flow chart depicting the steps taken by an initiating and target mobile device to establish a direct data transfer session in accordance with the present invention. Initially, the initiating mobile device opens a TCP port to listen for communications from the target mobile device  210 . The target mobile device has also similarly opened an SMS listening port to receive invitation SMS text messages at the specified SMS port  220 . The initiating mobile device then transmits its IP address (and TCP port) in an invitation SMS text message to the telephone phone number and a specified SMS port of the target mobile device  230 . The target mobile device receives the SMS text message containing the initiating mobile device&#39;s IP address (and TCP port) at the specified SMS port  240 . The target mobile device extracts the IP address and TCP port from the SMS text message and opens its own TCP port  250 . The target mobile device then transmits a request to establish a TCP connection to the initiating mobile device&#39;s IP address and TCP port  260 . The initiating mobile device receives this request  270  and a TCP connection is established between the IP addresses and TCP ports of the initiating and listening mobile devices and these devices are able to engage in a data transfer session over a reliable virtual connection  280 . 
     Alternative,  FIG. 3  depicts a flow chart for an alternative embodiment depicting steps to establish a direct data transfer session in accordance with the present invention. Initially, the initiating mobile device opens a TCP port to listen for communications from the target mobile device  310 . The initiating mobile device, through its supporting telephone company, then embeds its IP address (and TCP port) in the telephony ringing signal that is transmitted to the target mobile device  320 . For example and without limitation, the telephone company may use a frequency shift keyed (FSK) signal to embed the IP address (and TCP port) into the telephony signal, similar to the traditional techniques used to embed other special service information, such as a caller ID, in the traditional telephony context. The target mobile device receives the telephony ringing signal from the initiating mobile device  330 . The target mobile device extracts the IP address and TCP port from the telephone ringing signal and opens it&#39;s own TCP port  340 . The target mobile device than transmits a request to establish a TCP connection to the initiating mobile device&#39;s IP address and TCP port  350 . The initiating mobile device receives this request  360  and a TCP connection is established between the IP addresses and TCP ports of the initiating and listening mobile devices and these devices are able to engage in a direct data transfer session over a reliable virtual connection  370 . 
     While the foregoing detailed description has described the present invention using SMS, GSM, GPRS, and TCP/IP, other similar services and protocols may be used in a variety of similar environments in which the present invention may be implemented. For example and without limitation, rather than using SMS to transmit an IP address (and port) from the initiating mobile device to the listening mobile device through the devices&#39; telephone numbers, an alternative embodiment of the present invention might use a PIN-to-PIN messaging technology (as, for example, offered in RIM&#39;s Blackberry handheld devices) to transmit the IP address (and port) through unique PIN numbers associated with the mobile devices, or an alternative paging protocol using telephone numbers. Similarly, rather than using FSK to embed the IP address (and port) into the telephony ringing signal, an alternative embodiment of the present invention might use a Duel Tone Multi-Frequency (DTMF) transmission to embed the IP address and port. Furthermore, the present invention contemplates that the actual protocol used during an established IM session may also vary depending upon the preference of the implementation. For example and without limitation, Message Session Relay Protocol (MSRP) or any proprietary based protocol may be used during the IM session that is established in accordance with the present invention. Thus, various modifications, additions and substitutions and the like can be made without departing from the spirit of the invention and these are therefore considered to be within the scope of the invention as defined in the following claims.