PATENT ABSTRACT
A system and method for implementing an enhanced transport layer security (ETLS) protocol is provided. The system includes a primary server, an ETLS servlet and an ETLS software module. The primary server operates on a computer network and is configured to communicate over the computer network using a non-proprietary security protocol. The ETLS servlet also operates on the computer network and is securely coupled to the primary server. The ETLS servlet is configured to communicate over the computer network using an ETLS security protocol. The ETLS software module operates on a mobile device, and is configured to communicate over the computer network using either the non-proprietary security protocol or the ETLS security protocol Operationally, the ETLS software module initially contacts the server over the computer network using the non-proprietary security protocol, and subsequently contacts the server through the ETLS servlet using the ETLS security protocol.

PATENT DESCRIPTION
CROSS-REFERENCE TO RELATED APPLICATION  
         [0001]    This application claims priority from and is related to the following prior application: “Enhanced Transport Layer Security Handshake For Mobile Communication Devices,” U.S. Provisional Application No. 60/227,946, filed Aug. 25, 2000. This prior application, including the entire written description and drawing figures, is hereby incorporated into the present application by reference.  
         BACKGROUND  
         [0002]    1. Field of the Invention  
           [0003]    This invention relates generally to the field of computer network security protocols. More particularly, the invention provides an enhanced transport layer security (“ETLS”) protocol that is especially well-suited for use with mobile communication devices, such as Personal Digital Assistants, cellular telephones, and wireless two-way e-mail communication devices (collectively referred to hereinafter as “mobile devices”).  
           [0004]    2. Description of the Related Art  
           [0005]    Security protocols for establishing a secure connection to a computer network, such as the Internet, are known. A security protocol commonly used to securely connect to an Internet host is the Transport Layer Security (“TLS”) protocol, which was formerly known as the Secure Socket Layer (“SSL”) protocol.  
           [0006]    [0006]FIG. 1 is a signal flow diagram  10  illustrating the basic steps typically used to establish a secure connection between a client  12  and an Internet server  14  using the TLS protocol. In step  16 , an initial datagram is transmitted from the client  12  to the server  14  to establish contact and to identify the algorithms or languages that the client  12  is capable of supporting. Once the initial datagram is received, the server  14  typically accepts the connection and replies with a datagram that identifies the algorithms or languages that the server will support (step  18 ). In addition, the reply datagram from the server  14  typically includes a public key in a digital certificate that authenticates the identity of the server  14 . The digital certificate is generally acquired from a trusted third-party, such as VeriSign™ or some other certificate authority, which verifies that the public key belongs to the server  14 . In addition, the public key typically has an associated private key that is maintained only by the server  14 , whereby data encrypted with the public key can only be decrypted using the private key.  
           [0007]    In steps  20  and  22 , the client  12  negotiates a session key with the server  14 . The session key is typically a random number generated by the client  12  that is used for only one fetch-response operation between the client  12  and server  14 . The random session key is typically first used to encrypt some random data as “proof of the key.” The session key and the data are then encrypted with the public key and transmitted to the server in step  20 . The session key and “proof of key” data are decrypted by the server using its private key. The “proof of key” data is then further decrypted with the session key. Then, in step  22 , the server typically transmits the “proof of key” data back to the client  12  to establish that it has properly received and decrypted the session key.  
           [0008]    Once the TLS public key has been exchanged and a session key has been negotiated, a secure TLS socket is established, and application data may be securely transmitted between the client  12  and server  14  using the session key (step  24 ). By utilizing this four-pass handshake between a client and a server each time a communication is initiated, the TLS protocol ensures both the authenticity of the server and the originality of the transmission. For example, to illustrate the importance of originality, if a user has communicated with a bank server via a client to electronically transfer money from an account, the four-pass TLS handshake prevents the transfer operation from being repeated by “replaying” the same encrypted message from either the same client or another client if the communication was intercepted.  
           [0009]    Although the TLS protocol provides a secure connection to a server, this protocol is not well-suited for mobile applications because the datagrams transferred in the TLS four-pass handshake typically contain a relatively large amount of data that cannot be quickly transferred over a wireless network. Therefore, in order to reduce the number of datagrams transferred over the wireless network, mobile applications commonly utilize a Wireless Application Protocol (“WAP”) to establish a secure connection with an Internet server.  
           [0010]    [0010]FIG. 2 is a block diagram illustrating a typical mobile communication system  30  utilizing the Wireless Application Protocol (WAP). In this system  30 , a service request from a mobile device  32  that is addressed to a server  34  is encoded using a Wireless Transport Layer Security (WTLS) protocol and transmitted through a wireless gateway  36  to a WAP Gateway  38 , which typically acts as a proxy to the Internet. The wireless gateway and WAP gateway may or may not be co-located. Typically, the WAP Gateway  38  has its own digital certificate, signed by a trusted third-party that is used by the mobile device  32  to validate its authenticity. Once the WTLS-encrypted service request is received, the WAP Gateway  38  generally establishes a TLS connection over the Internet with the server  34 . The service request is then decrypted by the WAP Gateway  38 , re-encrypted using the TLS protocol and sent over the Internet to the server  34 . To respond to the service request, the server  34  typically transmits TLS-encrypted data to the WAP Gateway  38 , which is then decrypted and re-encrypted using the WTLS protocol and transmitted to the mobile device  32 . Although this system  30  is typically faster than the TLS protocol for mobile applications, it leaves a gap in the secure link, thereby risking that data may be intercepted while it is in plaintext format in the WAP Gateway  38 .  
         SUMMARY  
         [0011]    A system and method for implementing an enhanced transport layer security (ETLS) protocol is provided. The system includes a primary server, an ETLS servlet and an ETLS software module. The primary server operates on a computer network and is configured to communicate over the computer network using a non-proprietary security protocol. The ETLS servlet also operates on the computer network and is securely coupled to the primary server. The ETLS servlet is configured to communicate over the computer network using an ETLS security protocol. The ETLS software module operates on a mobile device, and is configured to communicate over the computer network using either the nonproprietary security protocol or the ETLS security protocol. Operationally, the ETLS software module initially contacts the server over the computer network using the non-proprietary security protocol, and subsequently contacts the server through the ETLS servlet using the ETLS security protocol. 
       
    
    
     BRIEF DESCRIPTION OF THE DRAWINGS  
       [0012]    [0012]FIG. 1 is a signal flow diagram illustrating the basic steps typically used to establish a secure connection between a client and an Internet server using the TLS protocol;  
         [0013]    [0013]FIG. 2 is a block diagram illustrating a typical mobile communication system utilizing a Wireless Application Protocol (WAP);  
         [0014]    [0014]FIG. 3 is a signal flow diagram illustrating a wireless communication between a client and a server using an enhanced transport layer security (“ETLS”) protocol;  
         [0015]    [0015]FIG. 4 is a block diagram of an exemplary ETLS system illustrating a secure connection between a mobile device and an HTTP server using the ETLS protocol; and  
         [0016]    [0016]FIG. 5 is a flow diagram of an exemplary method for securely communicating between a mobile device and a network server using the ETLS protocol. 
     
    
     DETAILED DESCRIPTION  
       [0017]    Referring now to the remaining drawing figures, FIG. 3 is a signal flow diagram  40  illustrating a wireless communication between a client  42  and a server  44  using an enhanced transport layer security (“ETLS”) protocol. The client  42  may be any system operating on a mobile device that is capable of wirelessly accessing a computer network. The server  44  preferably includes a primary server, such as an HTTP server  46 , and an ETLS servlet  48 , both operating on a computer network, such as the Internet. The ETLS servlet  48 , discussed in more detail below with reference to FIG. 4, is preferably a JAVA™ servlet operating on the HTTP server  46 , but could alternatively be some other server-side mechanism such as a CGI script. The ETLS servlet  48  is preferably installed on the HTTP server  46  with its own uniform resource locator (URL), which is added to a custom HTTP response header along with an ETLS public key.  
         [0018]    In step  50 , the client  42  attempts to open a secure connection with the server  44 . At this point, the client  42  has not yet detected the ETLS servlet  48 , and, therefore, uses a non-proprietary security protocol such as the TLS protocol. The TLS four-pass handshake, discussed above with reference to FIG. 1, is performed in steps  50 - 56 . In steps  50  and  52 , the client  42  and the server  44  determine which operations or languages they have in common, and a TLS public key in a digital certificate is transferred to the client  42 . In steps  54  and  56 , a random TLS session key is negotiated. Then, in step  58  the initial service request from the client  42  is encrypted with the TLS session key and transmitted to the HTTP server  46 . The HTTP server  46  decrypts the service request and transmits its initial encrypted response in step  60 . Along with the encrypted data, the initial response  60  from the HTTP server  46  also includes the custom HTTP response header with the URL of the ETLS servlet  48  and the ETLS public key. The ETLS public key is preferably generated by the ETLS servlet  48 , and has an associated ETLS private key that is maintained exclusively by the ETLS servlet  48 . The client  42  preferably stores the ETLS public key and associated URL in a memory location on the mobile device. Thereafter, each time the client  42  establishes a secure connection to the server  44 , it uses the ETLS public key and associated URL to communicate through the ETLS servlet  48 .  
         [0019]    Steps  62 - 68  illustrate two secure ETLS transmissions between the client  42  and the server  44  after the ETLS public key and associated URL have been received and stored by the client  42 . To establish a secure connection using the ETLS protocol, the client  42  first establishes a random ETLS session key and encrypts it with the ETLS public key received from the custom HTTP response header. The client  42  then uses the ETLS session key to encrypt the bulk data that makes up its service request to the server  44  and also to encrypt a digital time-stamp. In step  62 , the client  42  transmits the data to the ETLS servlet, preferably in the form of an HTTP POST request that includes the encrypted session key, service request and time-stamp. Once the ETLS servlet  48  has received the HTTP POST request, the request is decrypted and compared to a connection log to establish that the transmission is original. At this point, the security of the communication has been established, and the ETLS servlet  48  may perform a fetch-response operation with the HTTP server  46 . Then, once a response from the HTTP server  46  has been returned, the ETLS servlet  48  encrypts the response with the ETLS session key and transmits it to the client  42  in step  64 . The ETLS protocol, including the operations of the digital time-stamp and the connection log, are discussed in more detail below with reference to FIG. 4.  
         [0020]    Steps  66  and  68  illustrate that each subsequent communication between the client  42  and the server  44  may be performed using the same two-step ETLS handshake described above with reference to steps  62  and  64 . In this manner, the ETLS protocol enables secure communications between a mobile device and an Internet server without requiring the lengthy, multiple transmissions commonly associated with non-proprietary security protocols, such as the TLS protocol.  
         [0021]    [0021]FIG. 4 is a block diagram of an exemplary ETLS system  70  illustrating a secure connection between a mobile device  72  and an primary server  74  using the ETLS protocol. Cross-referencing FIGS. 3 and 4, the ETLS system  70  shown in FIG. 4 illustrates the ETLS connections made in steps  62 - 68  of FIG. 3, and after the initial TLS connection shown in steps  50 - 60  of FIG. 3. The ETLS system  70  includes the mobile device  72 , the primary server  74 , a wireless gateway  76 , the ETLS servlet  78  and the connection log  80 . The primary server  74 , ETLS servlet  78  and connection log  80  are located on a computer network, such as the Internet, and are preferably protected behind a common firewall  82 . Communications between the mobile device  72  and the computer network are preferably made through the wireless gateway  76  using any known Web browser-type software designed for use on a mobile device. The mobile device  72  preferably also includes an ETLS software module  71  that is configured to establish a secure connection with the computer network using either the ETLS protocol or a nonproprietary security protocol such as the TLS protocol.  
         [0022]    To send a service request to the primary server  74  using the ETLS protocol, the mobile device  72  preferably establishes a random ETLS session key that it uses to encrypt the service request, and encrypts the session key using the stored ETLS public key for the ETLS Servlet  78 . In addition, to protect against “replay” communications, an electronic time-stamp is also preferably generated by the mobile device and encrypted using the ETLS session key. Then, the encrypted service request, session key and time-stamp are all bundled in an HTTP POST request, or some other suitable transfer mechanism, and transmitted through the wireless gateway  76  to the ETLS servlet  78 .  
         [0023]    When the HTTP POST request is received at the ETLS servlet  78 , the ETLS session key is preferably decrypted with the ETLS private key that is maintained by the ETLS servlet  78 . The ETLS session key is then used by the ETLS servlet  78  to decrypt the service request and time-stamp. Preferably, a digital certificate from the primary server  74  was received and stored by the mobile device  72  when it first contacted the primary server  74  using a nonproprietary security protocol. Therefore, the identity of the primary server  74  has already been verified. The link is not yet secure, however, because a multi-pass handshake, such as the TLS handshake, was not used to negotiate the ETLS session key and establish that the transmission is original. The ETLS servlet  78  thus preferably protects against “replay” communications by comparing the decrypted service request and time-stamp with previous transmissions stored in the connection log  80 . In this manner, if the ETLS servlet  78  receives an encrypted HTTP POST request that includes a service request and time-stamp that is identical to that of a previous transmission stored in the communication log, then the servlet  78  will recognize that the service request is not an original communication, and will preferably ignore the service request. In a preferred embodiment, the communication log stores all of the service requests and time-stamps received by the ETLS servlet  78  within a pre-determined time period. Alternatively, the ETLS servlet  78  may save only the time-stamps or some other data, such as an ordinal number, indicating the originality of the transmission.  
         [0024]    Once the HTTP POST request has been decrypted by the ETLS servlet  78  and compared with the previous transmissions stored in the connection log  80 , a secure link between the mobile device and the ETLS servlet  78  has been established. The decrypted service request may then be transmitted from the ETLS servlet  78  to the primary server  74 , which performs the desired operation and returns a response to the ETLS servlet  78 . Because the ETLS servlet  78  and the primary server  74  operate behind the common firewall  82 , the non-encrypted data may be securely transferred using a standard transfer protocol, such as HTTP. Once the response from the primary server  74  is received by the ETLS servlet  78 , it is encrypted with the ETLS session key and transmitted through the wireless gateway  76  to the mobile device  72 . At the mobile device  72 , the response is decrypted with the session key. Then, if a new service request is desired, a new session key may be generated by the mobile device  72 , and the above described process repeated.  
         [0025]    [0025]FIG. 5 is a flow diagram of an exemplary method for securely communicating between a mobile device and a network server using the ETLS protocol. The method begins at step  92  in which communication is established between a mobile device and a network server operating on a computer network, such as the Internet. Once communication with the computer network has been established, the mobile device preferably accesses an internal memory location at step  100  to determine if an ETLS public key and an ETLS servlet URL have previously been saved for the particular network server. If so, then the mobile device recognizes that a secure link may be established using an ETLS servlet operating in connection with the server, and an ETLS handshake is performed starting at step  108 . If the mobile device does not have a stored ETLS URL and public key for the server, however, then a secure socket should preferably be opened with the server using a non-proprietary security protocol, such as the TLS protocol (step  102 ). After a secure socket has been negotiated with the server, the mobile device may then send an encrypted service request to which the server may respond with an encrypted TLS response (step  104 ). If the server is equipped with an ETLS servlet (step  106 ), then the TLS response sent by the server in step  104  will preferably include a custom HTTP response header that identifies the ETLS public key and the associated URL for the ETLS servlet, which is stored on the device in step  107 . The device then waits for a request for the next connection at step  109 . If the server is not equipped with an ETLS servlet (step  106 ), however, the device preferably waits until the device requests the next connection at step  109 .  
         [0026]    At step  108 , the mobile device preferably begins the ETLS handshake by generating a session key and encrypting it with the ETLS public key previously received from the server in the custom HTTP response header. At step  110 , the service request from the mobile device and a digital time-stamp are both encrypted using the session key (step  110 ). The digital time-stamp preferably includes the time and date that the transmission takes place. Then, at step  112 , the encrypted service request, time-stamp and session key are transmitted to the ETLS servlet, preferably in the form of an HTTP POST request or some other suitable transfer mechanism.  
         [0027]    When the HTTP POST request is received by the ETLS servlet, the ETLS session key is decrypted using a private key maintained exclusively by the ETLS servlet, and the decrypted session key is then used to decrypt the service request and digital time-stamp (step  114 ). At step  116 , the digital time-stamp is compared with those of previous transmissions stored in a connection log that is maintained by the ETLS servlet. If the time-stamp matches that of a previous transmission stored in the connection log, then the transmission is not original (step  118 ), and the service request is preferably ignored by the ETLS servlet (step  120 ). If the transmission is original (step  118 ), however, then the digital time-stamp is saved to the connection log (step  122 ) to prevent the transmission from being “replayed” in subsequent communications. In alternative embodiments, both the time-stamp and service request may be stored in the connection log and compared with the HTTP POST request, or the time-stamp may be replaced with some other means for determining that the request is original, such as an ordinal number.  
         [0028]    In step  124 , a secure link has been established and a fetch-response operation is performed between the ETLS servlet and the server to perform the function indicated in the service request from the mobile device. Then, in step  126  the response from the server is encrypted by the ETLS servlet using the session key and is transmitted to the mobile device. The response is decrypted by the mobile device at step  128 , and a new service request may then be initiated by the mobile device at step  109 .  
         [0029]    The embodiments described herein are examples of structures, systems or methods having elements corresponding to the elements of the invention recited in the claims. This written description may enable those skilled in the art to make and use embodiments having alternative elements that likewise correspond to the elements of the invention recited in the claims. The intended scope of the invention thus includes other structures, systems or methods that do not differ from the literal language of the claims, and further includes other structures, systems or methods with insubstantial differences form the literal language of the claims.