SECURE ELECTRONIC COMMERCE
Secure transactions are achieved over a public network by using a private network to handle the sensitive information of the transaction. When a client requests a product from a vendor server over a public network, the vendor server notifies a facilitation server on the public network. This results in the client receiving a set of computer readable instructions from the facilitation server. The set of instructions provide access instructions to a transaction server system on the private network so that sensitive transaction information is sent to the transaction server system on the private network rather than over the public Internet. Where the sensitive information is credit card information, the transaction server system may obtain authorisation for the transaction from a financial institution and then notify the vendor accordingly. Where the sensitive information is the identity of a user of the client, the transaction server may selectively authorise the transaction without the vendor being apprised of the identity of a user of the client. Secure communications may also be achieved by sending sensitive communications over the private network.
This application claims the benefit under 35 U.S.C. § 120 of patent application Ser. No. 10/081,265 filed Feb. 22, 2002 and entitled “SECURE ELECTRONIC COMMERCE,” which in turn claims the benefit under § 119(e) of U.S. Provisional Application Ser. No. 61/270,611 filed Feb. 23, 2001 and entitled “SECURE ELECTRONIC COMMERCE,” all of which are incorporated herein by reference in their entirety as if set forth in full.
BACKGROUND OF THE INVENTIONThis invention relates to enhancement of the security of network transactions.
Electronic commerce over the public Internet has enjoyed significant growth. However, there are concerns over the security of transactional information sent over the public Internet. One approach to address these concerns has been the advent of so-called “secure sites” (which are usually identified by the high level address of “https”, where the concluding “s” stands for “secure”). These sites encrypt communications to achieve security over the public Internet. While secure sites do provide a significant measure of security, encrypted data packets sent to and from these sites may be intercepted leading to the possibility that they may be decrypted by sophisticated hackers.
Thus, there remains a need for an approach to electronic commerce which better ensures the security of such commerce.
In some instances, a prospective consumer of electronic data may wish to remain anonymous. An anonymous transaction, by its nature, provides transaction security. Thus, there is also a need for an approach to electronic commerce which provides anonymity.
SUMMARY OF INVENTIONSecure transactions are achieved over a public network by using a private network to handle the sensitive information of the transaction. When a client requests a product from a vendor server over a public network, the vendor server notifies a facilitation server on the public network. This results in the client receiving a set of computer readable instructions from the facilitation server. The set of instructions provide access instructions to a transaction server system on the private network so that sensitive transaction information is sent to the transaction server system on the private network rather than over the public Internet. Secure communications may also be achieved by sending sensitive communications over the private network.
According to one aspect of the invention, there is provided a method for enhancing security of network transactions, comprising: receiving, over a public Internet, information relating to a pending transaction between a vendor server and a client; sending a message addressed to said client over said public Internet with a set of computer readable instructions having transaction-specific information, said set of computer readable instructions comprising access instructions for connecting said client to a transaction server system on a private network such that sensitive information relating to said transaction is directed to said transaction server system.
According to another aspect of the invention, there is provided a method for enhancing security of network purchase transactions, comprising: receiving, over a public Internet, information relating to a pending purchase transaction between a vendor server and a client; sending a message addressed to said client over said public Internet with a set of computer executable instructions for determining resources of said client for connecting to a private network.
According to a further aspect of the invention, there is provided a method for enhancing security of network transactions, comprising: receiving information relating to a pending transaction over a secure link, said information including a transaction identifier, access information for a data product, and a purchase amount; determining an appropriate chargeable telephone number based upon said purchase amount; storing said transaction identifier, said telephone number, and said access information; and returning said transaction identifier and said telephone number over said secure link.
According to another aspect of the invention, there is provided a computer readable medium storing computer-readable instructions which, when read by a client, cause the client to: dial and establish a connection to a specific telephone number over a telephone network; send a transaction-specific identifier over said connection; receive a message over said connection with a universal resource locator (URL) and password; drop said connection; connect to said URL over a public Internet; and display said password.
According to a further aspect of the invention, there is provided an internet service provider having a border gateway protocol table with an entry mapping at least one Internet Protocol address to a port connected to a private network.
Other aspects of the invention will be apparent from the following description in conjunction with the drawings.
In the figures which illustrate example embodiments of the invention,
Turning to
An ISP 26a may become a member ISP which can provide for secure transactions in accordance with this invention by being provisioned with a link 46 to private network 34 and with software from computer readable medium 126a. The software adds a mapping from one or more addresses to the port of the ISP 26a connected to link 46. Each of these addresses is in the form of an Internet Protocol (IP) address and is referred to herein as a “private network address”.
The mapping from a private network address to a port of the ISP connected to link 46 is accomplished by adding an entry to the Border Gateway Protocol (BGP) table of ISP 26a, which entry is configured as one that cannot be exported. By way of explanation, in Internet Protocol systems, autonomous systems (ASs) exchange network reachability information using BGP. An ISP (which may comprise one or more routers under a single technical administration) is an AS. Each AS maintains a BGP routing table which includes current routes between itself and the ASs to which it connects directly (through a port). (As will be appreciated by those skilled in the art, in some instances, certain ASs with indirect connections to a given AS may also be included in the table.) ASs with direct connections to a given AS are known as the “neighbours” of the given AS. The table entry for a particular neighbouring AS also indicates which network addresses (representing other, non-neighbouring, ASs) are reachable by the particular neighbouring AS. An AS broadcasts an update message when there is a change in its table (except that entries configured as “no export” are not broadcast). When an AS receives data (an IP packet) addressed to a certain IP address, it uses its BGP table to find a neighbouring AS which can reach the destination address and ports the data to that neighbouring AS. Further detail regarding the BGP may be obtained from, for example, RFC 1771 BGP-4, March, 1995, the contents of which are incorporated herein by reference. As detailed hereafter, by adding an entry in the BGP table of the ISP 26a, this invention makes use of the BGP to port messages addressed to a certain network (IP) address (or to one of a group of certain addresses) to the transaction server 36 on a private network. In other words, the BGP table entry references the transaction server 36 on the private network as if it were a neighbouring AS on the public Internet. Transaction server 36 is, however, a cloaked server, meaning it has no public Internet address.
A vendor server 24a may become a member vendor server which can provide for secure transactions in accordance with this invention by being provisioned with software from computer readable medium 124a. The software conditions the operation of the vendor server as is described hereafter and also allots the vendor server a vendor identifier. Additionally, optionally, vendor server 24a is provisioned with a separate link 48 to private network 34.
Facilitation server 28 and transaction server 36 are provisioned with software for operating according to this invention from computer readable medium 128 and 136, respectively.
This software includes data for database 40, namely, an identifier (IP address) for each member ISP. Additionally, the data may include the private network address(es) given to each member ISP.
Each of computer readable media 124a, 126a, 128, and 136 may be, for example, a disk, memory chip, or a file downloaded from a remote source.
As shown in FIG.1a, facilitation server 28 has a memory 52 which stores an applet shell 54 and applet download instructions 56 (set up as a Web page). As will be appreciated by those skilled in the art, an applet (such as a JAVA™ applet) is a small set of computer readable instructions used to perform a small application.
The operation of communications system 20 is described in conjunction with
A client 30a connects to a member vendor web site on member vendor server 24a through member ISP 26a and public Internet 22 in a conventional fashion (
Whenever the member vendor server 24a receives an order, it creates a transaction identifier and sends an IP message to facilitation server 28 over public Internet 22. This message includes (1) its pre-registered vendor identifier; (2) the purchase amount; (3) the IP address of the client making the purchase, and (4) the transaction identifier (
The facilitation server 28 receives the message from the vendor server and identifies the ISP from the client IP address. By way of explanation, as will be appreciated by those skilled in the art, a client IP address is allotted to the client by its ISP from a stable of IP addresses belonging to the ISP. (Each such IP address may either be associated with a specific client or assigned dynamically when the client logs on to the ISP.) The facilitation server 28 can identify the ISP from the client IP address by launching a directory name server (DNS) query over the Internet. The facilitation server then sends the information in the message from the vendor server, along with an identification of the ISP, to the transaction server 36 through firewall 42 (
On receiving the message from the facilitation server, the transaction server uses the address for the ISP 26a as an index into database 40 to determine the private network address associated with the ISP (
On receipt of the message from the transaction server (
The vendor server 24a receives the message from the facilitation server and redirects the client to the new URL in the message (
On receipt of the message from the applet, the ISP interrogates its BGP table with the received private network address (which, it will be recalled, is in the style of an IP address) in order to map the message to an output port (
It will be noted from the foregoing, that a member ISP need only one new entry in its BGP table, as well as a direct link to the private network, in order to operate in accordance with this invention. Further, it will be noted a client need have no permanent software load to take advantage of the invention. It will be apparent that the applet which is downloaded to the client, being provisioned with transaction-specific information, is useful in completing only one transaction. The actions taken by the applet are identified as S208 to S210 in
In the simplest case, the private network 34 is simply a set of direct end-to-end connections between connected elements. More typically, the private network is, for example, an asynchronous transfer mode (ATM) network. In such instances, a member ISP must be provisioned to handle ATM communications over the private network. Where a vendor server has a link to the private network, it would also need to be similarly provisioned. Such provisioning is believed to be within the skill of those skilled in the art and is, therefore, not further described.
Optionally, database 40 may be part of the transaction server 36.
Optionally, since the vendor server passes the facilitation server the IP address of the client (
Optionally, the private network address could be the same for each member ISP. In such instance, it could be a permanent part of an applet shell rather than being looked up by the transaction server.
The transaction identifier is used simply to ensure that data flowing in respect of a given transaction is properly associated with the given transaction. Optionally, the transaction identifier could be created by the transaction server rather than by the vendor server. In such instance, the vendor server may create a temporary transaction identifier which is passed in its message to the facilitation server and which the facilitation server returns when passing the applet URL to the vendor server.
A number of steps may be taken to further enhance the security of the system, as follows. Firstly, a session timer may be activated at the transaction server as soon as sensitive information arrives over the private network. If the transaction server cannot validate the transaction identifier and password within a pre-configured space of time, the connection is dropped. Secondly, the transaction server may have a byte counter such that if the number of bytes arriving from an ISP over the private network exceeds a pre-configured amount, the connection is dropped. An overlong validation process or receipt of too many bytes is suggestive of hacker activity. Thus, these steps reduce the prospects of any such activity causing difficulty. Also, all Internet communications with the facilitation server may be encrypted in a conventional fashion.
To provide access to a data product for a fee, it is common for a vendor to provide a purchaser with a location (URL) of a restricted site containing the data as well as a necessary username and password to access the site once payment for access to the data has been received. It is assumed that vendor server 74a is configured for this operation.
A vendor server 74a may become a member vendor server which can provide for secure anonymous data purchase transactions in accordance with this invention by being provisioned with software from computer readable medium 174a. The software conditions the operation of the vendor server as is described hereafter and also allots the vendor server a vendor identifier.
To prepare system 70 for operation, a request is made to the operator of PSTN 84 for a series of “900” numbers which will be switched through to “900” server 80. Additionally, a different dollar amount is requested to be associated with each “900” number. As will be understood by those skilled in the art, the “900” service provided by telephone companies (telcos) allow a subscriber to obtain a “900” number such that a caller to the number has a charge associated with the “900” number added to his or her telephone bill by the telco. Database 40 stores the series of “900” numbers along with the different dollar amount associated with each one.
The operation of communications system 70 is described in conjunction with
Client 90a connects to its ISP 76a and then to a vendor web site on vendor server 74a via the ISP 76a in a conventional fashion (
In response to the order, the vendor server 74a creates a transaction identifier and sends the facilitation server 78 a message with (1) its pre-registered vendor identifier; (2) the cost to be charged for the requested data product; (3) the URL of the restricted site to direct the client if the transaction succeeds (the “success URL”); (4) the username and password required for access to the restricted site; (5) the URL to direct the client if the transaction fails (the “failure URL”); and (6) the transaction identifier (
The facilitation server 78 sends this along to transaction server 86 (
In response to receiving the message from the transaction server 86 (
The vendor server 74a redirects the client 90a to the transaction URL (
The setup applet passes this configuration information back to the facilitation server and then terminates (
The “900” server uses the received transaction identifier as an index in to the database (S1204). Assuming that this returns a pending transaction record, the server checks that the called “900” number matches the “900” number in the pending transaction record. If yes, the applet running on the client is passed: (1) the success URL; and (2) a username and password (
As is conventional, the call from the client 90a will provide the “900” server with caller line identification (CLID) or calling party name display (CPND) information; this, for an anonymous transaction, is the sensitive information of the transaction. Where the “900” server passes the applet the success URL, the CLID and/or CPND information is stored by the “900” server in database 40 in association with the transaction identifier (
On receiving the success URL, the applet disconnects from the “900” server (where necessary, reconnecting the client to the public Internet 22 through its ISP) and directs the web browser of the client 90a to the success URL (
If the transaction identifier passed to the “900” server 80 does not correlate with what is in the database 40, the “900” server returns a failure URL to the applet (
From the foregoing, it will be apparent that the operation of the transaction applet is embodied in S809 to S816 of
Where the setup applet determines (
From the foregoing, it will be apparent that, in this instance, the operation at S809 to S816 involves actions of the user as well as of the transaction applet.
The charge for the “900” call will appear on the phone bill for the subscriber of the PSTN line from client 90a. The telco forwards the money received in payment of this charge to the operator of the “900” server 80 along with the identity of the customer (i.e., CLID and/or CPND information) who paid this money. The vendor for vendor site 74a bills the operator of the “900” server for the charge for the data which was requested by client 90a and associates the transaction identifier with this bill. The operator of “900” server 80 can correlate the received transaction identifier with the received customer identity information by virtue of having stored the CLID/CPND information in association with the transaction identifier. Thus, the “900” server operator can forward the money to the vendor after receiving it from the telco operator.
It may be noted that, unlike in the embodiment of
Optionally, a transaction identifier may be generated at the transaction server rather than the vendor server. In such instance, the vendor server passes the facilitation server a temporary transaction identifier which the facilitation server returns with its message to the vendor server containing the URL. Optionally, it may be the transaction server has available to it usernames and passwords for access to the restricted site. In such instance, this information need not be passed to the transaction server from the vendor server.
Optionally, the vendor server could send the facilitation server the client IP address along with the other information sent on receipt of an order confirmation (in S902). This would allow the transaction server to prompt the facilitation server to send an e-mail receipt to the client upon successful completion of a transaction. Also, in such instance, the facilitation server could message the client directly with the URL for the applets. To enhance security, the vendor server could send a message to the client advising the user to trust the message from the facilitation server and the facilitation server could use a digital certificate to prove its identity. As a further option, the facilitation server could simply send (digitally signed) applets directly to the client (through the client's ISP) rather than the URL for the applets.
As a further option, the information sent by the vendor server on receipt of an order confirmation (in S902) could also include a URL to direct the client to if the user aborts the transaction.
Optionally, the transaction server and “900” server could be combined as one server. Also, the database 40 could be part of this combined server.
While the system 70 of
Optionally, the set-up applet and transaction applet could be combined as a single applet. Appendix A sets out pseudo-code for an example JAVA™ combined applet suitable for use with clients running MS-EXPLORER™ under MS-WINDOWS™. Referencing Appendix A, at line 3 a main window of a graphical user interface is created. At lines 4 to 7 an attempt is made to load the transaction-specific parameters which had been stored with the applet (namely the transaction identifier, appropriate “900” number, and possibly a password). If, for whatever reason, the transaction-specific parameters fail to load, then the applet redirects the client's browser to a page of instructions to allow the user to manually dial the “900” number and engage in an interactive voice response (IVR) session with the “900” server in order to attempt to complete the transaction. The same result occurs due to lines 8 to 11 if, for whatever reason, the parameters do not pass a validation process (i.e., they do not make sense). At lines 12 to 15, appropriate security privileges are requested from the client web browser's JAVA™ virtual machine to allow the applet to run native code. If these security privileges are not obtained, again, a page of instructions is presented inviting the user to manually dial the “900” number and engage in an IVR session to attempt to complete the transaction.
Next, at line 16, the applet gets the list of configured modems at the client. In consequence of lines 17 to 22, if there is only one modem, this one is used. Otherwise, the user is queried which modem the applet should use. As a result of lines 23 to 26, if the user fails to select a modem, the IVR session page is presented. Lines 27 to 29 cause a disconnection from the ISP where the user has a dial-up connection without a shared modem. Next, consequent on line 30, the “900” number is dialled to connect the client to the “900” server. If, for whatever reason, the call to the “900” number does not go through, lines 31 to 38 of the applet result in the user being informed of the failure, reconnected to the ISP, and the IVR session page presented. If the call does go through, then, at line 39, the transaction identifier (and password, if any) is passed to the “900” server.
If the transaction fails to validate, then, in consequence of lines 40 to 48, a failure window pops up, the client is disconnected from the “900” server, reconnected to its ISP where necessary, and the client's web browser redirected to a failure URL. On the other hand, as a result of lines 49 to 55, if the transaction does validate, the applet is passed the success URL, username, and password. The applet then loads a receipt page and shows a success pop-up window displaying the username and password. Additionally, the client is disconnected from the “900” server and, if necessary re-connected to its ISP. The client's browser is then redirected to the success URL and, at line 56, the applet exits.
Turning to
An ISP can become a member ISP which can provide for secure communications by being provisioned with a link 246 to private network 34 and with software from a computer readable medium 228a, 228b. The software adds a mapping from one or more addresses, each of which is in the form of an IP address—referred to herein as “private network addresses”—to the port of the ISP connected to line 246. Each of these private network addresses represents a specific other member ISP. As detailed hereafter, by adding an entry in the BGP table of the ISP, this invention makes use of the RGP to port messages addressed to certain network (IP) addresses to the communications server 236 on a private network. In other words, the BGP table entry references the communications server 236 on the private network as if it were a neighbouring AS on the public Internet.
Communications server 236 is provisioned with software for operating according to this invention from computer readable medium 238. This software includes data for database 240, namely, for each member ISP, a mapping of each private network address given to the member ISP to another member ISP.
Each of computer readable media 228a, 228b, 238 may be, for example, a disk, memory chip, or a file downloaded from a remote source.
In operation, client 230a of member ISP 226a may connect to ISP 226a and send a secure e-mail message to a user of client 230b of member ISP 226b, by addressing the message to the user of client 230b at one of the private network addresses allocated for ISP 226b: i.e., the address has the form name@private-network-address. ISP 26a will map the private network address to its port 246 so that the message arrives at the communications server 236 on private network 34. Server 236 indexes the database 240 with the private network address of the message and determines from this the destination ISP 226b. The server 236 then directs the message to the destination ISP over the private network 34. The destination ISP 226b uses the “name” indication of client 230b in the address to direct the message to this client.
Using the described approach, a business with geographically separated offices could arrange for client stations in one office (which connect to the public Internet through one ISP) to securely communicate with client stations in another office (which connect to the public Internet through another ISP).
Other modifications will be apparent to those skilled in the art and, therefore, the invention is defined in the claims.
Claims
1-11. (canceled)
12. A method for enhancing transaction security for network transactions, comprising: at a transaction server:
- receiving sensitive information relating to a transaction from a client over a private
- network wherein said sensitive information comprises a credit card number and a
- personal identification number (PIN) or a debit card number and a PIN or E-wallet login information.
13. The method of claim 12 further comprising:
- receiving a purchase amount relating to said transaction;
- sending said sensitive information and said purchase amount to a financial institution; and
- receiving an approval or disapproval indication from said financial institution in reply.
Type: Application
Filed: Oct 29, 2018
Publication Date: Jun 20, 2019
Inventor: Mark ITWARU (Toronto)
Application Number: 16/173,562