Patent Abstract:
A method and associated system for Internet play of an instant lottery game includes supplying instant lottery tickets for purchase by players, with each of the instant lottery tickets having a game authorization code. The winning or loosing status of the instant lottery tickets is unknown to the players at the time of purchase. Each of the instant lottery tickets is provided with a unique prize claim code separate from the game authorization code. A web site is provided wherein a player enters the game authorization code via an Internet device to initiate play of the instant lottery game. The outcome of the game is then randomly determined and presented to the player via the web site. The value of a winning outcome is credited to a running tally associated with the lottery ticket and, upon the player cashing out to end the lottery game, a monetary value is assigned for the running tally associated with the unique prize claim code. The prize claim codes are stored and at defined periodic intervals, the prize claim codes are transferred to a lottery system central computer. For redemption of an instant lottery ticket, the player presents the prize claim code to a lottery redemption location wherein the presented prize claim code is verified with data from the transferred prize claim codes to determine a payout to the player for the lottery ticket.

Full Description:
PRIORITY CLAIM 
     The present application claims priority to U.S. Provisional Application Ser. Nos. 61/280,330 filed on Nov. 2, 2009, and 61/340,807 filed on Mar. 23, 2010. 
    
    
     FIELD OF THE INVENTION 
     The present application proposes a methodology and associated system for selling and redeeming lottery games over the Internet. The proposed methodology and system allow for enhanced gaming experiences of both deterministic outcome and dynamically determined outcome Internet-based games. Additionally, this application provides a secure methodology for allowing tickets to be sold and redeemed in conventional lottery retailer outlets that enable gaming over the Internet in compliance with laws concerning age and legal jurisdiction authentication. 
     BACKGROUND 
     Lottery games have become a time honored method of raising revenue for state and federal governments the world over. Traditional scratch-off and on-line games have evolved over decades and supply increasing revenue year after year. However, after decades of growth, the sales curves associated with traditional games seem to be flattening out. Consequently, both lotteries and their service providers (e.g., Scientific Games, GTech, Pollard Banknote, Infralot, etc.) are presently searching for new forms of gaming. 
     To date there has been much speculation about providing various lottery products to the consumer over the Internet. The benefits are obvious; greater accessibility and a richer gaming environment for the player will result in enhanced sales. However, there are various United States federal laws that bring into question the legality of such an enterprise. Specifically, laws that require proof that the Internet gaming experience took place within the jurisdiction of the lottery authority (e.g., a given state&#39;s boundaries) and require that the consumer of the lottery Internet product is of legal age. These are particularly challenging obstacles, given that a violation of either requirement (i.e., location or age authentication) could result in felony charges against the institution running the Internet lottery operation. 
     Additionally, any attempt at implementing a new legal (i.e., lottery based) Internet gaming product invariably involves developing new costly infrastructures for sales and redemption as well as the gaming environment itself. It is therefore highly desirable to develop a system for authenticating age and location for Internet gaming as well as ensuring that said system could be readily integrated into an existing lottery&#39;s infrastructure. 
     Partially because of these legal hurdles and auditing requirements, any proposed Internet lottery game to date has been of a deterministic nature—i.e., the outcome of the game is determined before it starts. While the Internet does offer the ability to enhance the deterministic gaming experience, the very nature of deterministic games limits the enhanced experience and ultimately causes the games to seem stale to experienced consumers. The lack of game-dynamic-player-input ultimately limits the Internet gaming experience. Thus, it is highly desirable to also develop an Internet gaming platform that not only conforms to legal requirements but also allows for dynamic play (e.g., a player is allowed to vary his bet and cash out at any time) resulting in a more fulfilling Internet gaming experience. 
     SUMMARY 
     Objects and advantages of the invention will be set forth in part in the following description, or may be obvious from the description, or may be learned through practice of the invention. 
     Described are a number of mechanisms that provide practical details for reliable deterministic and dynamic Internet gaming. Various means are also described for integrating Internet gaming into a lottery&#39;s existing logistical sales and redemption structure as well as age and location authentication based on these mechanisms. 
     In a particular embodiment, a method for Internet play of an instant lottery game includes supplying instant lottery tickets for purchase by players. Each instant lottery ticket has a game authorization code. The winning or loosing status of the instant lottery tickets are unknown to the players at the time of purchase. The method includes providing each of the instant lottery tickets offered for sale with a unique prize claim code that is separate from the game authorization code. A web site is provided wherein a player enters the game authorization code via an Internet device to initiate play of the instant lottery game. Once the instant lottery game is initiated by the player, the outcome of the game is randomly determined and presented to the player via the web site. The value of a winning outcome is credited to a running tally associated with the lottery ticket and, upon the player cashing out to end the lottery game, a monetary value is assigned for the running tally to the unique prize claim code for the lottery ticket. The prize claim code is stored and at defined periodic intervals, the prize claim codes having monetary values assigned thereto are transferred to a lottery system central computer. For redemption of the instant lottery ticket, the player presents the prize claim code to a lottery redemption location wherein the presented prize claim code is verified with data from the transferred prize claim codes to determine a payout to the player for the lottery ticket. 
     The Internet functionalities may be implemented in various ways. For example, in one embodiment, an Internet game server may be configured in communication with the lottery system central computer. In another embodiment, the Internet functionalities are implemented with the lottery system central computer that also functions as an Internet game server. 
     The lottery system central computer may also be configured for conducting an on-line draw lottery game wherein on-line lottery tickets are sold to players at retail locations, with the instant lottery tickets being offered to players at the same retail establishments and being redeemed at redemption locations for the on-line lottery tickets. In this embodiment, the prize claim codes having a monetary value assigned thereto are stored in a file that is transferred to the lottery system central computer at the defined periodic interval and loaded into a lottery validation system. The files for winning on-line lottery tickets are also loaded into the lottery validation system. The players may be notified of a time after the loading into the lottery validation system when they can redeem their instant lottery tickets. 
     In certain embodiments, the instant lottery tickets are printed real-time for the player at the time of purchase by lottery terminals that also print on-line lottery tickets. The method may include generating an ongoing database of the purchased instant lottery tickets that is used to verify the game authorization codes subsequently entered by players for Internet play of the instant lottery tickets. In another embodiment, the instant lottery tickets are pre-printed, with the method including generating a database of for all of the pre-printed instant lottery tickets offered for sale that is used to verify the game authorization codes entered by players for Internet play of the instant lottery tickets. 
     The method may further include the step of verifying the player&#39;s geographic location when the player accesses the web site for Internet play of the instant lottery game. 
     The present invention also encompasses a various embodiments of a lottery system for conducting Internet play of an instant lottery game in accordance with the methods discussed above. 
    
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
         FIG. 1  is a front plan view of a first representative example of a lottery-type instant ticket used to deposit funds for Internet gaming; 
         FIG. 2  is a front plan view of the first representative example of the lottery-type instant ticket used to deposit funds for Internet gaming of  FIG. 1  showing the scratch off coatings removed; 
         FIG. 3  is a front plan view of a lottery sponsored web page that allows for the Internet funds of  FIG. 1  and  FIG. 2  to be used to play a virtual slot-type machine on the Internet; 
         FIG. 4  is a view of the back of the lottery lottery-type instant ticket used to deposit funds for Internet gaming of  FIGS. 1-2 ; 
         FIG. 5  is a flow chart illustrating a first method of producing, distributing, and selling lottery-type instant ticket used to deposit funds for Internet gaming of  FIGS. 1-2  and  4 ; 
         FIG. 6  is a flow chart illustrating details of the operation of the server portion for Internet gaming of  FIG. 5 ; 
         FIG. 7  is a flow chart of a second method of producing, distributing, and selling lottery-type tickets used to deposit funds for Internet gaming of  FIG. 3 ; 
         FIG. 8  is a flow chart of a third method of producing, distributing, and selling lottery-type tickets used to deposit funds for Internet gaming only in this embodiment, the outcome of the game is predetermined by the Game Activation Code (GAC); and, 
         FIG. 9  is a representative example of many of the possible layers of a multi-tiered age and location identification and authentication algorithm; 
         FIG. 10  is a flow chart illustrating several methods that may be used to authenticate a consumer&#39;s identity and, by inference, his age as indicated by  FIG. 9 ; 
         FIG. 11  is a flow chart illustrating a possible method of sorting and flagging IP addresses of Internet devices based upon listings maintained by the lottery or third parties and as indicated in  FIG. 9 ; 
         FIG. 12  is a flow chart illustrating a possible method of approving IP address locations based upon ping times as also indicated in  FIG. 9 ; 
         FIG. 13  is a flow chart illustrating possible methods of geolocating Internet devices based upon signals available from GPS and/or Cell tower signals as also indicated by  FIG. 9 ; 
         FIG. 13A  is a flow chart illustrating in more detail certain functions of the flow chart of  FIG. 13 ; 
         FIG. 14  is a flow chart illustrating a possible method of geolocating Internet devices based upon a WiFi Positioning System as also indicated by  FIG. 9 ; 
         FIG. 15  is a flow chart illustrating a possible method of geolocating Internet devices based upon a landline, Voice Over IP (VoIP), or Cell telephone system as also indicated by  FIG. 9 ; and 
         FIG. 16  is a flow chart illustrating a possible method of geolocating one Internet device based upon a Confirmation Code generated by a second Internet device without sending precise locational information as also indicated by  FIG. 9 . 
     
    
    
     DETAILED DESCRIPTION 
     Reference will now be made in detail to embodiments of the invention, one or more examples of which are illustrated in the figures. Each example is provided by way of explanation of the invention, and not meant as a limitation of the invention. For example, features illustrated or described as part of one embodiment can be used with another embodiment to yield a third embodiment. It is intended that the present invention include these and other modifications and variations. 
       FIGS. 1 and 2  depict a first representative example of Internet tickets  100 ,  105 , and  110  having two components: a prepaid money amount  115 ,  120 , and  125  and a removable Scratch-Off-Coating (SOC)  130  lottery instant ticket portion obscuring GACs until the ticket(s) are purchased by a consumer. These instant lottery tickets  100 ,  105 , and  110  are provided as one embodiment of a suitable lottery ticket, however it should be understood that other lottery-type tickets, for example, on-line tickets printed in real time, can be used and may be more desirable in some applications. In this example, the tickets  100 ,  105 , and  110  resemble traditional instant-win tickets and can be purchased in the normal manner at a lottery retailer. After purchase, the consumer removes the Scratch-Off-Coating (SOC)  130  to reveal the, previously hidden, GAC indicia data  135 — FIG. 2 . The consumer then uses his computer, smart telephone, or other Internet Device (IDE) to visit the specified web site  140  ( 155  in the instructions on the back of the ticket as shown in  FIG. 4 ) via Internet browser or special application and enter the GAC indicia data  135 . 
     In this embodiment, the web site would validate the submitted GAC and determine the location of the IDE and, assuming the device is within the lottery&#39;s jurisdiction, would enable an Internet game in which the outcome of the game is determined by an on-line pseudorandom generator and not by the GAC indicia data  135 . As shown in  FIG. 3  one possible example of an on-line pseudorandom generator game, is an Internet slot-machine type game (web page  200 ) wherein the consumer enters the GAC indicia data  135  by typing or other means into a GAME CODE entry window  202 . After the code has been correctly entered, the information would be sent to the lottery by clicking or otherwise actuating the PLAY virtual button  201 . After receiving the GAC, the lottery computer would, by various methods, validate the code and determine the location of the consumer&#39;s IDE and, if several criteria are met, the total number of CREDITS would appear in a display  204 . The total number of CREDITS  204  being derived from the price (e.g.,  115 ,  120 , or  125 ) of the ticket purchased divided by the cost per point (e.g., 5¢ as shown in  209 ). The consumer would now be allowed to start playing the game. 
     The CASH OUT virtual button  203  is present because this example reflects an embodiment of an Internet game wherein the outcome is determined by an on-line pseudorandom generator as the consumer plays the game and not predetermined by the ticket code  135 . Thus, the consumer has the option to actuate the CASH OUT virtual button  203  at any time, with the number of credits present  204  when the consumer actuates the CASH OUT virtual button  203  reflecting the amount of money he has won. 
     To play the game, in this example, the consumer would select the desired points per BET  206  via the BET ONE  205  or BET MAX  207  virtual buttons. The BET MAX  207  virtual button differs from the BET ONE  205  in that actuating the BET MAX  207  virtual button typically will bet the maximum number of points and the maximum number of lines (consistent with the remaining Credits  204 ) and spin the reels. If the consumer chooses the BET ONE button, he can select the desired points per bet in increments of one for each depression of the button. He would then select the number of lines on the virtual slot-type machine  212  he would like to play per spin by actuating one or more of the virtual line check marks  214 . As shown in  FIG. 3  the user interface could highlight the selected line(s)  214  on the virtual slot-type machine (e.g., by adding a background color to the entire line) to provide additional visual feedback to the consumer that multiple lines have (or have not) been selected by the virtual row check marks  214 . Additional visual feedback  213  can also be provided by explicitly displaying the total number of lines selected resulting in the total amount wagered per spin (4 points per spin in this example  213 ). In addition to the previously discussed visual feedback indicators, a SPINS REMAINING  210  counter could be available, providing an indication of how many spins (plays) remain based upon the total number of CREDITS  204  and the POINTS PER SPIN  213  currently selected. Once the correct wager is programmed, the consumer would actuate the virtual SPIN “lever”  211 . The virtual slot-machine  212  would spin its virtual reels and eventually stop with winning or losing patterns displayed as identified by a prize table display  208 . The consumer could continue to play the Internet game until he elects to CASH OUT  203  or no longer has any CREDIT showing in the display  204 . 
     Assuming CREDITS  204  remain and the consumer actuates the CASH OUT virtual button  203 , there are numerous methodologies available for the consumer to receive his winnings from the lottery. For example, the consumer could request a check, or direct deposit to a specified account, or debit card account, or request a CREDIT transfer to another game directly through the Internet interface  200 . Alternatively, the Internet interface  200  could allow the consumer to print a ticket on a local printer that would include a unique redemption code identifiable by any of the lottery&#39;s terminals available throughout its jurisdiction. Another alternative would be for the standard lottery-type instant ticket inventory number  145  ( FIG. 4 ) to be used as the code to allow redemption at a lottery retailer. However, this example has the disadvantage that existing lottery redemption systems, for security reasons, are designed to greatly restrict or forbid any changes in the instant ticket database after the tickets are placed on sale—especially prize values. A better alternative for the embodiment of the game being discussed (i.e., the outcome is determined by an on-line pseudorandom generator as the consumer plays the game) is to add a second PRIZE CLAIM code  150  to the lottery-type instant ticket in addition to the standard inventory number  145 . This PRIZE CLAIM code  150  could be embodied as a barcode and human readable code as shown in  FIG. 4  and as is obvious to anyone skilled in the art, the PRIZE CLAIM code  150  could be embodied by other means (e.g., magnetic stripe, OCR, star code, etc). 
     The unique PRIZE CLAIM code  150  has the advantage of being readily adaptable to existing lottery redemption systems. For example, in one possible embodiment the unique PRIZE CLAIM code  150  could emulate the structure of the lottery&#39;s existing on-line ticket (e.g., Power Ball, Pick 3, Pick 4, etc.) data structure. Since on-line tickets typically are issued in real-time as a wager is made at a lottery terminal, their associated unique serial number data structure functions only to reference the wager for a future drawing. When the future drawing occurs, all of the previous wagers stored in the on-line database are scanned to determine the winners. After the post-drawing scan is completed, winning on-line ticket serial numbers are automatically credited with the correct winning amounts. Thus, by emulating the structure of the lottery&#39;s existing on-line ticket data structure in an Internet ticket unique PRIZE CLAIM code  150 , the Internet tickets  100 ,  105 , and  110  could be readily sold without allowing any redemption until the game is played on the Internet. The existing lottery on-line system would readily accommodate this scenario by initially logging all PRIZE CLAIM codes  150  on all tickets for a future drawing. When the consumer actuates the CASH OUT virtual button  203  and any CREDITS  204  remain, the system will automatically calculate the cash equivalent and log the credit to the associated PRIZE CLAIM code  150  in a drawing winners&#39; file. Periodically, say once every twenty-four hours, the drawing winner file would be transferred from the web servers and loaded onto the lottery&#39;s existing validation system. Once loaded, the lottery validation system would then automatically instruct a retailer to pay the consumer the amount credited when he actuated the CASH OUT virtual button  203 . To assist in database management, the PRIZE CLAIM code  150  can be algorithmically linked to the GAC indicia data  135  (e.g., keyed hash, indicia data  135  is a cipher text version of PRIZE CLAIM code  150 , etc.) so long as the, hidden until purchased, indicia data  135  cannot be deduced from the, readily displayed, PRIZE CLAIM code  150 . Alternatively, the PRIZE CLAIM code  150  and indicia data  135  could be two algorithmically unrelated blocks of data only linked by a secure database. Obviously, in this embodiment where the PRIZE CLAIM code  150  is linked to a drawing, there would be some notice given to the consumer that “Winning tickets can be redeemed twenty-four hours after cashing out” or words to the same effect. 
       FIG. 5  illustrates a first method of producing and selling the Internet tickets of the type  100 ,  105 ,  110  and associated Internet game  200 . In this case it is contemplated that the Internet tickets would be distributed within an existing distribution network already in place for instant lottery games and the tickets could be redeemed with the existing system ( 301  in  FIG. 5 ). However, in this case, since the outcome of the Internet game  200  is not predetermined, there can remain the added tasks of transferring winning amounts to the drawing winner database when the consumer actuates the CASH OUT virtual button  203  with CREDITS  204  remaining. 
     Beginning at block  300  on the flowchart illustrated in  FIG. 5 , the institution responsible for printing a lottery&#39;s instant tickets produces a run of Internet tickets of the type  100 ,  105 ,  110  to fund the Internet game  200 . As is normal in this type of production process, the produced instant tickets are delivered to the lottery and placed on sale at the lottery&#39;s retailers  304 . As is also routine in instant ticket production, a digital file representing the shipping and validation information for the entire instant ticket run is delivered to the lottery&#39;s central site system  303 . Under normal operations this file would be used for both inventory control as well as validation, however in this embodiment the tickets of the type  100 ,  105 ,  110  simply fund an Internet game  200  and therefore the winning or losing status of a given ticket is not known at the time of production or sale. Therefore, the instant ticket database will be utilized in this embodiment primarily for logistical control and accumulating sales data  305 . 
     As shown in the flowchart illustrated in  FIG. 5 , there is one more deliverable  302  from the instant ticket printer, in this embodiment, that is normally not required for instant tickets. This On-Line Drawing Database  302  contains all of the PRIZE CLAIM codes  150  from all of the tickets of the type  100 ,  105 ,  110  produced. In theory, the delivery of this on-line database  302  to the lottery&#39;s existing central site system  301  is optional, since all of the on-line serial numbers delivered will be for a virtual drawing at a future date with no immediate value. However, most lottery redemption systems require that a file exists for all sold on-line drawing serial numbers before a drawing can occur. This being the case, the delivered on-line database file  302  would function as the sold on-line drawing tickets, even though the instant tickets of the type  100 ,  105 ,  110  are put on sale (i.e., not yet sold) at the time the file  302  is delivered. 
     A related or identical copy of the same on-line database is also delivered  302 ′ to the web server running the Internet game  200 . This copy of the database is used by the server to: determine the authenticity of received GAC indicia data  135 , ensure that no GAC indicia data  135  is credited twice, and to generate the correct PRIZE CLAIM codes  150  for the tickets associated with winning games (i.e., where the consumer actuates the CASH OUT virtual button  203  with CREDITS  204  remaining) in the Win File database  308 . It should be noted, that the related or identical copy of the on-line database  302 ′ could be simply replaced with the on-line database  302  resident at the lottery&#39;s central site  301  with all Internet gaming transactions being conducted by the lottery&#39;s central site system. Indeed, in new applications this embodiment may be more desirable, however for adding Internet gaming to existing lottery central site systems  301  that were not originally designed to accommodate this type of interface, it may be desirable to implement the Internet functionality on separate servers for ease of integration. Obviously, these separate servers could be physically located at the same location as the existing lottery central site system  301 . 
     Next in this example, the consumer purchases a ticket  306  and visits the specified Internet gaming site  200  via web browser, specific application, or other means. When the consumer enters the GAC indicia data  135  by typing or other means into a GAME CODE entry window  202  and actuates the PLAY button  201 , the entered data is transferred to the server containing the on-line database  302 ′ where it is both authenticated and checked to ensure that the same GAC indicia data  135  has not been used before. If the GAC indicia data  135  is incorrect or has been used before the appropriate error message will be returned to the consumer and game play will not be allowed. However, if the GAC indicia data  135  is authentic and unused, the lottery server will then attempt to validate that the consumer is physically located within the lottery&#39;s jurisdiction at a block  306 ′. Assuming the consumer&#39;s location is confirmed, he will be allowed to play the Internet game  200  until he exhausts all credits or actuates the CASH OUT virtual button  203  with CREDITS  204  remaining  307 . In the latter case, the number of credits remaining will be transformed into a cash equivalent and logged with the consumer&#39;s ticket&#39;s PRIZE CLAIM code  150  on the Win File database  308 . After completing the game, the consumer will receive a notice indicating when (if not immediately) he can cash his ticket at a lottery retailer. 
     Virtual drawings will be periodically conducted  310  at the lottery central site  301  for the Internet game  200 . The time period for the virtual drawing is flexible and could be every twenty-four hours, or even as often as every minute. The purpose of the virtual drawing is to load the winning tickets PRIZE CLAIM codes  150  onto the lottery&#39;s central site system  301  so that the existing infrastructure of retailers can cash tickets that became winners after Internet game play. By conducting a virtual drawing for these winning tickets as they are created, the existing lottery central site system  301 , on-line drawing software accepts the newly generated winners without significant modification and generates the appropriate Drawing Database of Winners  311 . Winning PRIZE CLAIM codes  150  from previous drawings can simply be rolled over into the latest Drawing Database of Winners  311  with the old file being deleted or modified depending on the nuances of the lottery&#39;s central site software system  301 . 
     As soon as the consumer has waited the predefined time period (if any)  309  he can cash his ticket (assuming it was determined to be a winner by Internet game play). To cash his ticket, the consumer simply goes to any lottery retailer who then scans the ticket&#39;s PRIZE CLAIM code  150  on their lottery terminal  312 . The authorization to pay the consumer would then be given in a similar manner to any on-line (i.e., drawing) winning ticket ( 311  and  312 ) with the winning ticket being logged at the central site as paid  314  and the consumer receiving payment  313 . 
     The previously described system can be completely integrated into the existing lottery&#39;s system  301  or set-up with different components for the Internet gaming portion. In the latter case, the Internet portion can even be operated by a different entity than the lottery&#39;s central site  301 . This separation of functionality has the potential to both reduce liability and enhance security. In either case, it is essential that particular attention to the security of the Internet game portion  200  be applied since the game&#39;s outcome is not predetermined. As illustrated in  FIG. 6 , all of the Internet game  200  logical components associated with the outcome of the game (other than the decision when to CASH OUT  361 ) are located on the Internet Game Server  351  and not the consumer&#39;s IDE  350 . This separation is essential because various web browser applications (e.g., Java) can be easily decompiled at the consumer&#39;s device and are susceptible to various forms of Spoofing attacks. Even if the consumer&#39;s interface is supplied by a custom application (e.g., iPhone app), the fact that it runs on a platform outside of the control of the lottery makes it susceptible to fraudulent attacks. It is therefore, undesirable to log accounting information and decide if a particular play (spin) is a winner on the Consumer IDE  350 . 
     In the method of  FIG. 6 , the overall system functionality and distribution is a subset to the embodiment of  FIG. 5 . Thus, this embodiment can generally be the same as the previous embodiment, providing more detail on the interaction between the Consumer&#39;s IDE  350  and the Internet Game Server  351 . These details start on  FIG. 6  with block  352  where the consumer purchases a ticket and goes to the associated web site. The first time the Consumer IDE  350  visits the web site operated by the Internet Game Servers  351 , the IDE may need to download  353  a specific application compiled for his device or a web based (e.g., Java) application that runs on a hardware independent platform. Once the required application is downloaded, the consumer would be prompted to enter the GAC indicia data  135  by typing or other means into a GAME CODE entry window  202 , which was created by the downloaded application, and then passed by the application to the On-Line Game Server  354 . Assuming the GAC indicia data  135  is correct and has not been used before and the consumer&#39;s location is verified to be within the lottery&#39;s jurisdiction, the On-Line Game Server  354  will provide the Consumer&#39;s IDE  350  application with the correct amount of credits to display (based on the GAC indicia data  135 ) and will authorize it to proceed with play of the Internet game  200  by passing an unique Session IDentification (SID) code back to the application  353 . This same SID code and total credits available are also passed to the logic that calculates a play&#39;s (spin&#39;s) outcome  355  resident on the Internet Game Server  351 . 
     At this point, the consumer makes a wager and executes a play (spin)  358  on the Internet game  200 . The details of this wager are then transmitted to the Spin Outcome &amp; Running Tally module  355 . Module  355  then calculates the outcome for the first play (spin) that has not yet occurred on the Consumer Game application  358 . The module  355  calculates the outcome for the first play by using a seed from a pseudo-Random Number Generator (RNG)  356 . Depending on the outcome of the play, the Spin Outcome &amp; Running Tally module  355  will either credit or debit the running credit total for the consumer&#39;s game based on the wager that he made and determine if enough credits remain for another play  357 . The outcome of the play is then passed from the Spin Outcome &amp; Running Tally module  355  to the Consumer Game application  358  along with the credits remaining after the play. When the Consumer Game application  358  receives this information it will animate play (e.g., spin the reels  212  on the Internet game  200  display) with the play concluding as instructed by the Spin Outcome &amp; Running Tally module  355  with the CREDIT window  204  incrementing or decrementing depending on the play&#39;s (spin&#39;s) outcome. If no credits remain  359 , the Consumer Game application  358  will end the game  360 . Otherwise, the application  358 / 359  will allow the consumer to either make another wager and play or to CASH OUT  203  and end the game with winnings  361 . If the consumer elects to CASH OUT  203 , the application will transmit this decision to the game server  351  and the monetary equivalent of credits will be added to the associated consumer&#39;s ticket&#39;s PRIZE CLAIM code  150  on the Win File  362  at the server. As previously mentioned, in this embodiment, the information from the Win File  362  will eventually be transferred to the lottery&#39;s central site system  301  so that the ticket can be redeemed at any retailer location by the consumer  364 . 
     There are many possible ways of configuring the Spin Outcome &amp; Running Tally module  355  and RNG module  356  of  FIG. 6 . One possibility is for each play (spin) the Outcome module  355  simply queries the RNG module  356  for the latest output. For any of these applications, the RNG  356  should be either a True hardware Random Number Generator (TRNG) or a software pseudo-RNG like a Linear Congruential Generator (LCG) or preferably a Mersenne Twister that receives a starting seed from real world data (e.g., a hash of the time the On-Line Game Server  354  was first contacted combined with the GAC indicia data  135  received when contacted). However, if a TRNG is selected, care should be taken to provide cryptographic authentication that the seed received from an external TRNG truly was created by that device. It is arguable, that the software RNG is preferable for this application if its input seeds are determined by an auditable sequence of events (e.g., hash chain of previous seeds coupled with a new seed). In either case, it may be desirable to utilize only one random seed per GAC indicia data  135  game, thereby enabling a better audit trail. 
     No matter what methodology is selected for the Spin Outcome &amp; Running Tally module  355  and RNG module  356  of  FIG. 6 , it is essential that all credit bets, wins, and losses as well as all spin results be calculated and recorded on the Internet Game Server  351 . These recorded transactions as well as the outcome of the RNG module  356  will constitute an audit trail that can be used to resolve any claims by the consumer that his IDE  350  informed him that he was a big winner when his ticket redeemed for a much smaller value (if any). To secure this audit trail it may be desirable to maintain a secure hash chain of all transactions. By maintaining all calculations at the Internet Game Server  351 , the possibilities of the IDE  350  erroneously displaying an incorrect win or total are greatly minimized. Wording can also be added to the back  155  of the ticket of type  100 ,  105 ,  110  ( FIG. 4 ) stating that a review of the audit file is the final arbitrator in all disputes. 
     As will be appreciated by anyone skilled in the art, the aforementioned is simply one embodiment of a multiplicity of possible variations. For example, as is previously discussed, this embodiment can also be funded with on-line tickets printed real-time at the time of purchase. Indeed this embodiment does result in a simpler system as shown in  FIG. 7 , albeit with modifications to the existing lottery central site  301  to accommodate generation of GACs tied to monetary values as well as less tangible advertising and the virtual currency metaphor inherent with the instant scratch-off Internet tickets of type  100 ,  105 , and  110 . 
       FIG. 7  illustrates a second method of producing and selling lottery-type tickets used to deposit funds for Internet gaming of  FIG. 3  type  200 . In this case it is contemplated that the ticket funding the Internet game would be sold within an existing distribution on-line network already in place for drawing-based-games (e.g., Power Ball, Pick 3, Pick 4, etc.). Thus, in this embodiment the consumer would purchase a ticket from the retailer with the ticket and associated GAC and prize claim code (ticket serial number) printed real-time at the time of purchase  315 . When the purchase is made, the existing lottery central site system  301  On-Line Drawing Database  317  would be updated with the purchased ticket serial number (prize claim code) awaiting a drawing. Also, as before, a related or identical copy of the same on-line database is also delivered  317 ′ to the web server running the Internet game  200 . Again, this copy of the database is used by the server to: determine the authenticity of received GAC, ensure that no GAC is credited twice, and to generate the correct prize claim codes for the tickets associated with winning games (i.e., where the consumer actuates the CASH OUT virtual button  203  with CREDITS  204  remaining) in the Win File database  308 . As before, the consumer would then take the purchased ticket and go to the directed web site to enter the GAC printed on the ticket  316 . (In this embodiment there is no need to hide the GAC because the on-line ticket is only printed after purchase.) The remainder of this second method embodiment is identical to the first embodiment and will not be repeated here for sake of brevity. 
     Yet another possible embodiment, where the instant scratch-off Internet tickets of type  100 ,  105 , and  110  result in a predetermined game outcome, is shown in  FIG. 8 . This embodiment has the advantage of a simpler system with virtually no modifications to the existing lottery central site  301 . However, this embodiment has the disadvantage of deterministic outcome (i.e., no CASH OUT virtual button  203  or option) which, from a consumer&#39;s perspective, can create the perception of less control and consequently lower perceived chance of winning. 
     In this method, illustrated in the flow chart of  FIG. 8 , Internet tickets of type  100 ,  105 , and  110  would be produced as before  325 . However, in this embodiment there is no need for a separate PRIZE CLAIM code  150  on the back of the ticket ( FIG. 4 ) or an associated On-Line Drawing Database of type  302  and  302 ′ ( FIG. 5 ). Rather, this embodiment only requires that a standard Instant Ticket Database  303  be maintained on the lottery central site system  301  as well as (optionally) a related or identical Instant Ticket Database  303 ′ on the Internet game server. 
     Returning to the physical placement of tickets of the type  100 ,  105 ,  110  on sale at block  304 , as before, the consumer purchases a ticket  306  and visits the specified Internet gaming site via web browser, specific application, or other means. When the consumer enters the GAC indicia data  135  by typing or other means into a GAME CODE entry window, the entered data is transferred to the server containing the Instant Ticket Database  303 ′ where it is both authenticated and checked to ensure that the same GAC indicia data  135  has not been used before. If the GAC indicia data  135  is incorrect or has been used before, the appropriate error message will be returned to the consumer and game play will not be allowed. However, if the GAC indicia data  135  is authentic and unused, and the consumer&#39;s location is verified  306 ′, the consumer will be allowed to play the Internet game  326 . Again, in this embodiment, the outcome of the Internet game is predetermined by the ticket GAC indicia data  135  so the consumer will be required to play a specified number of rounds or complete a given number of tasks depending on how the Internet game is designed. When the game is concluded, the consumer can then take the ticket to the retailer who will scan the instant ticket barcode  327  to pass the data to the lottery&#39;s central site instant ticket validation system for payment authorization  328 . If the ticket is authentic and the system returns a payment authorization, the consumer is paid  329  with the sales and redemption data both being recorded on the lottery&#39;s instant ticket database  330 . 
     It should be noted, that an optional feature of this embodiment would allow for individual ticket activation when the consumer logs onto the web site and plays the game  326 . This individual ticket activation would have the benefit of stopping a consumer from simply purchasing the ticket and asking the retailer if it was a winner without playing the game thereby ensuring that the consumer experienced the enhanced Internet gaming experience. This option would have the additional advantage that retailers would spend less time validating losing tickets. Individual ticket activation could be accommodated with existing lottery central site systems  301  by simply reducing the pack size to one ticket. 
     While the previously described embodiments explain mechanisms that provide various means for integrating Internet based games into a lottery&#39;s existing logistical sales and redemption structure, no mention of practical details for reliable Internet age and location identification and authentication has been described. Age and location identification and authentication are best served by layering two or more methodologies each having very low error rates. Layering allows the age/location system to be both flexible and effective, while minimizing the number of false rejects. For example, let&#39;s assume a location system only employs one layer, but that layer is 99.9% accurate. That is, if someone is attempting to use the system outside of the lottery&#39;s jurisdiction, there is a 1-in-1000 chance that the system will fail to detect and block the errant user. In other words the false accept and false reject failure rates are both 0.1%. Now, let&#39;s assume that only 1 in 10 million users of an Internet gaming site is attempting to play a game outside of the lottery&#39;s jurisdiction. Despite the high (99.9%) level of accuracy, because of the small percentage of users attempting to defraud the system, this hypothetical system will generate 10,000 false rejects for every real fraud attempt. This kind of usage-failure rate would make the hypothetical system impractical—i.e., by the time a real attempt to defraud the system occurs, legitimate users will have stopped using the system because it falsely blocked them too many times from playing a game. To prevent this problem, the lottery might be forced to greatly reduce the detection logic threshold criteria or turn off the logic completely. However, as shown in  FIG. 9 , with a layering architecture based on a foundation of low error rate methods, we can gradually build-up a reliable system that (for most practical purposes) ensures that the lottery&#39;s age and location identification and authentication requirements are met while virtually eliminating false rejects. However, as is obvious to anyone skilled in the art, the various layers described below are examples only and in some instances, one or more layer(s) can be deleted or changed while still maintaining the high level of age and location authentication. For example, in both the age and location authentication layering examples the first layer (i.e., purchasing a physical lottery ticket from a licensed retailer) may be eliminated in an attempt to increase sales by allowing purchases directly over the Internet. 
     The first level of age and location authentication can be imposed by the process of purchasing and redeeming a lottery ticket at an existing retail location  400 . Indeed this, time honored methodology has been in place with modern lotteries for over three decades without any significant legal challenges. Thus, the purchase and redemption of tickets, as described in the previous embodiments, provides the same assurance that a consumer is of legal age and within a lottery&#39;s jurisdiction as in the past. However, since the new element “Internet game play” has been added, it may also be necessary to add requirements for age and location authentication that surpass or replace what has been previously accepted (since the consumer must now convince a computer that he is of legal age and in the jurisdiction). There are numerous embodiments that can add additional layers of authentication either by themselves or in conjunction with each other. 
     Traditionally there are three ways to authenticate an individual and, by inference, his age: “by something he knows”, “by something he has”, and “by something he is” as collectively shown in  FIG. 10 . In other words, Internet age authentication is simply a subset of traditional identification and authentication of an individual and the three traditional methods of individual authentication are therefore also applicable to age authentication. 
     The first method employs the “something he knows” criteria. The most obvious “something” being passwords, PIN codes, lock combinations, etc. At the time of purchase 1000 of the Internet gaming ticket, the retailer could (assuming he is convinced that the consumer is of legal age  1002 ) ask the consumer to enter (for example) a Personal Identification Number (PIN) into a keypad or provide the retailer a password  1008 . This PIN or password (i.e., “Known Data”) could then be logged  1009  along with data of the ticket sold (e.g., scan of the ticket&#39;s barcode) to the consumer  1018 . At this point, the consumer would be tied by “something he knows” to the ticket that enables Internet gaming. When the consumer attempts to play an Internet game, the system could simply prompt him for the PIN or password (Data) before allowing play to commence. With this level of authentication, the Internet gaming system would gain another layer of assurance that the consumer attempting to play the game is the consumer who purchased the ticket and is therefore of legal age. Also, it should be noted, that this level of “something he knows” authentication does not necessarily require the consumer to identify himself personally to the lottery system—i.e., the PIN or password is the only authentication data “known” to the lottery system. This additional layer of authentication incrementally reduces the possibility that an unauthorized youth below the legal age is attempting to play an Internet game. 
     The second method of traditional authentication is “something he has”. The “something” might be a physical key, a membership card, a driver&#39;s license, or a mobile telephone card (an “Object” essentially a different form of “Data”). At the first level, the lottery ticket provides significant age authentication by the forced entry of the ticket GAC  135  and the “Known Data”—thereby authenticating that the ticket was purchased at an authorized lottery retailer and (presumably) with the consumer age verified by the retailer prior to purchase  1002 . Of course, the “something he has”—i.e., “Object”—item can be added  1010  (e.g., a barcode identity card, scan of drivers&#39; license barcode), but the basic principle remains the same. Like the “something he knows” method, anyone can give this “something he has” to anyone else—e.g., just as an instant lottery ticket can be passed from one person to another. Nevertheless, this second criteria serves to further reduce the likelihood of underage game play. 
     While the previous methods probably provide more than sufficient age authentication, yet another level of age authentication would be to adopt the method “something he is”. More specifically, it is an example of “something that is a physical part of his body.” Ostensibly, this “something” would be biometrics data  1016  including: voice-prints, fingerprints, hand geometry, facial geometry, handwritten signatures, iris and retina scans, etc. While some of these technologies may be a bit exotic and intrusive for the purposes of Internet gaming, it should be noted that technological advances might make some of the “something he is” age authentication far more practical as well as far more difficult to bypass. For example, microphones, fingerprint scanners, and cameras common in laptop computers may make face and voice biometrics practical for lottery authentication. Additionally, a signature long used by credit card companies as a second layer of “something he is” authentication (the first layer being “something he has”—i.e., the credit card), is relatively simple to collect and could be employed in the form of mouse movement or camera image for another layer of Internet gaming age authentication. 
     Like the sale of conventional scratch-off instant tickets, the purchase and redemption of tickets at an authorized lottery retailer does not necessarily ensure that the actual gaming experience occurred within the lottery&#39;s legal jurisdiction—e.g., a consumer could purchase a ticket within the lottery&#39;s jurisdiction, play the game outside the jurisdiction, and return to the jurisdiction to redeem winning tickets. This portability of play is a particularly vexing problem for Internet gaming. Federal law requires that all aspects of Internet gaming occur within the geographical jurisdiction of the hosting lottery including the actual game play. While this requirement can be met on the lottery support side by careful placement of the Internet servers and central site, the nature of the Internet itself, permitting action at a distance, makes it extremely difficult to ensure that the actual gaming experience occurs within a lottery jurisdiction. 
     Like age authentication, the first layer of location identification and authentication can be provided by the sale and redemption of the ticket  400  enabling play on the Internet. Since the ticket would only be sold in authorized lottery retail locations, which by definition are within the jurisdiction of the lottery, the sale and redemption of the ticket would ensure, at the very least, that these two transactions are conducted within the lottery&#39;s jurisdiction. Additionally, the sheer inconvenience of a consumer having to travel to the lottery&#39;s area of jurisdiction to purchase and redeem prizes would eliminate a large majority of casual users outside of the lottery&#39;s jurisdiction. 
     Since any device connected to the Internet must have an Internet Protocol (IP) address, a second layer of location identification and authentication could be provided by the IP address  402  of the device attempting to use a lottery Internet game web site. IP addresses  402  consist of four integers separated by periods (also called a ‘dotted-quad’) and look something like: 75.90.50.255. Since these numbers are usually assigned to Internet Service Providers (ISPs) within region-based blocks, an IP address can often be used to identify the region or general location from which a device is connecting to the Internet. If an IP address is known to be static, associated with a small entity or individual, and within a lottery&#39;s jurisdiction, it is a reasonable assumption that the game access request and associated activity will be taking place within a lottery&#39;s jurisdiction and could therefore be permitted access to the Internet game without the need for any more authentication. 
     However, because there are limited numbers of IP addresses, the ISPs typically issue IP addresses in a dynamic fashion out of a “pool” of IP addresses (Using DHCP or Dynamic Host Configuration Protocol). What this fact means is that instead of relying on a fixed IP address, an IDE will be assigned an IP address that is available from a subnet or “pool” that is assigned to the network. Though, if the pool of dynamically assigned IP addresses is known to be within a lottery&#39;s jurisdiction, the system could grant access with a reasonable level of confidence—though not as high a level of confidence as the static IP address method. Referring to  FIG. 11 , these known static and dynamic IP addresses can comprise a “white list”  1104  used by the lottery server as an important resource in verifying the consumer&#39;s IDE. The lower confidence level associated with dynamic IP addresses results from the possibility that a portable IDE (e.g., dial-up modem on a laptop computer, mobile smart telephone, satellite transceiver, etc.) could be assigned a dynamic IP while the portable device is outside a lottery&#39;s jurisdiction—i.e., it is much less likely that static IP addresses would be associated with portable devices. 
     The converse to known good IP addresses within a lottery&#39;s jurisdiction is known bad IP addresses both inside and outside of a lottery&#39;s jurisdiction. These IP addresses can be: geographically outside of a lottery&#39;s jurisdiction, proxy servers, known Tor server addresses, America On Line (AOL), etc. By maintaining a “black list” of IP addresses  1108 , the system can immediately inform a potential user that his location is not within the lottery&#39;s legal jurisdiction and, due to federal law, he cannot play the lottery&#39;s Internet game from that location  1114 . 
     There is, however, another category of IP addresses that could be granted access  1106  assuming other location identification and authentication is attained. These IP addresses would include such entities as: AOL, IP addresses on the border of the lottery&#39;s jurisdiction, etc. These types of IP addresses could be filed under a “gray list” designation  1110 , where access might be permitted  1116  assuming a more rigorous location authentication and identification test has been successfully completed—e.g., 802.11 (Wi-Fi) authentication. 
     Finally, there is the possibility that the consumer is attempting to connect to the lottery&#39;s Internet game site from a previously unknown IP address  1112 . In this event, the unknown IP address can be treated as a special case, where access may be permitted  1116  assuming a more rigorous location authentication and identification test has been successfully completed similar to the gray list. 
     Fortunately, portable devices (especially those using dial-up modems and satellite transceivers) and remote relays (e.g., Tor) can often be detected by simply sending a ping (i.e., series of data packets sent over the Internet to a specific device in order to generate a response from that device) to the suspected portable device  404  (Layer  3 ,  FIG. 9 ). As shown in  FIG. 12 , if the IP address is a member of the white list  1200 , a ping is sent to the consumer&#39;s IDE  1202 . If the ping response time is less than a specified time period “X” (e.g., 50 ms)  1208  there is a reasonably high level of confidence that the device requesting access is not portable or relayed, and assuming the dynamic IP address is within a lottery&#39;s jurisdiction (white list), the location is valid and play should be permitted  1214 . If the reply to the ping is greater than the prescribed time  1208 , then additional pings  1210  can be sent to the requesting device to determine if the initial long ping reply was an anomaly (e.g., a server was busy at the time of the first ping) or normal for this connection. If the additional pings continue to produce a response time in excess of “X” ms  1212 , the device requesting Internet play is most probably portable or a relay and additional location authentication may be desired  1216 . This additional pinging is practical because a series of pings can occur within one or two seconds and require no action by a human being, making repeated attempts at ping-based location authentication less intrusive to the gaming process than techniques that require human intervention. 
     If the IP address is a member of the Gray or Unknown list  1200 , game play might be allowed if additional authentication is obtained  1216 . 
     There may be circumstances in which additional authentication is necessary or the consumer is connecting with the lottery&#39;s Internet site by a smart mobile telephone, laptop computer, or other IDE that is equipped with some version of Radio Frequency (RF) receiver—e.g., Global Positioning System (GPS), Cell phone, or WiFi receiver  406  in  FIG. 9 . In some cases, depending upon the model of smart phone, provider network, and service plan, GPS data may be available. The GPS can determine the location of the telephone or other IDE and then, with the consumer&#39;s permission, transmit that information, or other activation information, to the lottery&#39;s Internet site. Once the location data is received, the Internet site will determine if the game play will be within its legal boundaries and allow (or forbid) game play. It should be noted, that GPS provides accurate location authentication (i.e., 10-meter resolution) in “open sky” environments, like rural areas or highways. In urban areas and indoors, tall buildings and ceilings block GPS receiver&#39;s reception, resulting in serious performance deficiencies in time-to-first-fix, accuracy, and availability. In such situations A-GPS (Assisted-GPS), where terrestrial GPS broadcasts are used to supplement the GPS signal, can still be utilized by GPS equipped Internet devices to give location authentication in most cases, albeit with a slight degradation in accuracy but not significant enough to interfere with lottery location requirements. As shown in  FIG. 13 , if the location authentication process is handed off to Layer  4   a  &amp;  b ,  1216 , and a GPS signal is available  1300 , and the consumer&#39;s device, network, and service plans are compatible, then in one embodiment, the IDE will determine its position and ask permission to send the data to the lottery&#39;s web site  1302 . Assuming permission is granted  1304 , the data is sent to the lottery computer  1305  which then determines if the consumer is located within the lottery&#39;s jurisdiction  1306  and permits  1308  or denies  1316  access to the gaming website. If permission is not granted  1304 —e.g., for security or personal reasons—the consumer can be given the option to send a Location Verification Code (LVC) instead. This LVC could be designed to not contain specific information about the consumer&#39;s location except that he was within the lottery&#39;s jurisdiction. Of course, in such case, the IDE would make the decision that it was located within the lottery&#39;s jurisdiction using a dedicated software algorithm that would be made available for download. If the consumer also chooses to deny permission to send an LVC, the location application can check for a cell tower signal  1310 . 
     There are cases where a GPS signal is simply not available or no GPS receiver is present on the mobile system or the consumer has refused to grant permission for the more accurate GPS data or LVC to be passed to the lottery. In these cases, cell tower triangulation may be utilized to provide generalized location results with an accuracy of approximately 200 to 1,000 meters. This accuracy, for all but state border situations, would provide sufficient resolution for lottery location authentication purposes. Various service providers maintain a worldwide database of cell tower locations. This database can be licensed for a modest fee, allowing the lottery&#39;s application on a mobile telephone to utilize the cell towers that it is detecting to determine if the consumer is within the lottery&#39;s legal boundaries. Note that mobile telephones can detect the Cell ID from towers at a far greater distance than they can connect to the tower for communications. As shown in  FIG. 13 , the procedure is similar to GPS location. If there is no GPS signal  1300 , or the consumer has refused permission to pass GPS data to the lottery  1304  but a Cell phone signal is available  1310 , the system may be able to geo-locate by triangulation or other means. If the IDE is localized, permission is requested to send the data to the lottery&#39;s website  1312 . If permission is granted at  1314 , locational data is sent to the lottery at  1315  and the lottery&#39;s computer verifies the consumer is within its jurisdiction  1306  and permits  1308  or denies access to the game  1316 . If the consumer denies permission to send detailed locational information  1314  (e.g., perhaps for security or personal reasons), he can, as before, be given the option to send an LVC instead. If the consumer also chooses to deny permission to send an LVC, the location application can hand off to the WiFi Positioning System (WPS) layer  4   c ,  1318 . If cell signals are not available  1310 , the process could also be handed off to the WPS  1318  application. 
     The permission to send LVC information can be handled in a manner similar to that shown in  FIG. 13A . The decision block  1304  is expanded to show that if the consumer denies permission to send detailed locational information  1320 —e.g., GPS co-ordinates or street, number, city, and state—then he is given the option to send, for example, a 3 digit LVC  1322 . It is clear that three digits cannot precisely locate the consumer and, as a result, may be an acceptable alternative and allay his privacy concerns. If the LVC contains too many digits, the consumer may think his actual location is embedded. If the consumer accepts the LVC option  1322 , the dedicated software application determines (from GPS, Cell, or WPS data) if the IDE is within the lottery&#39;s jurisdiction and creates the LVC based upon instructions from the lottery server—e.g., “578”=within jurisdiction any other number=outside jurisdiction. Of course this LVC changes on a regular basis perhaps as a function of time, date, SID, a combination of these data or other criteria. The LVC is displayed to the consumer at  1324 . The consumer enters the LVC via the keypad or other means at  1326  and the data is sent to the lottery  1305 . If the consumer refuses permission to send the LVC  1322 , then the decision is handed off to the Cell Tower decision block at  1310  (as before). Of course this same procedure can also be used in place of the Cell Permission Granted block  1314  in which case, if the consumer refuses permission to send the LVC, the application would hand off to the WPS layer  1318 . 
     Most personal computers are not equipped with data modems and therefore, cell tower triangulation is not an option for location authentication with these devices. Fortunately, there is a proven system for location authentication that uses the 802.11 (Wi-Fi) transceiver built into virtually every personal computer and other Internet devices on the market today. WPS can determine location based on databases of known Wi-Fi access points by using the Media Access Control (MAC) addresses of nearby 802.11 wireless access points. MAC addresses are a unique identifier assigned to most network adapters by the manufacturer for identification purposes. WPS typically performs best where GPS is weakest, —e.g., in urban areas and indoors—providing service similar to GPS without GPS hardware or signals. Even when consumer platforms are equipped with GPS receivers, WPS can be used to provide complementary services when GPS is not available or the consumer refuses permission to use GPS data. The accuracy of WPS is reported to be 20 to 30 meters, with near 100% coverage in urban areas. Like Cell ID, MAC address Wi-Fi signals can be detected for WPS at a far greater distance than they can be used for communications. Various service providers maintain a worldwide database of Wi-Fi “access points”. This database can be licensed for a modest fee, allowing the lottery&#39;s application on a mobile telephone or other IDE to utilize these access points to determine if the consumer is within the lottery&#39;s legal boundaries. As shown in  FIG. 14 , if a WPS signal is available  1400 , a software application can determine the consumer&#39;s location and ask permission to send the information to the lottery&#39;s web site  1402 . If permission is granted  1404 , locational data (or LVC) is sent to the lottery&#39;s server  1405 . The lottery&#39;s application can determine if the consumer is located within the jurisdiction  1406  and allow  1408  or prohibit  1410  game play. As in the case of GPS and Cell ID, if the consumer does not want to send detailed locational information at  1404 , he can be given the opportunity to send an LVC instead. If WPS signals are not available or the consumer refuses permission  1404 , the location procedure can be handed off to a fifth layer of authentication  1412 . 
     Returning to the problem of providing location authentication under questionable cases (e.g., long ping on a dynamic IP address  1212 , grey or unknown lists  1200 , consumer refuses permission  1404 , other options not available, etc.), as shown at  412  in  FIG. 9 , a fifth layer of verification still remains. Assume the lottery&#39;s server encountered one or more “permission denied” messages anywhere in the previous process—e.g., at  1304 ,  1314 ,  1322 ,  1404 , or others. That means the consumer&#39;s IDE has access to at least one RF receiver-based source of locational data but the consumer chose to deny its use. Then at  1500 , because permission was previously denied, there still remains a “land line” option for location verification. The lottery server could automatically generate a unique numerical code and send it to the consumer&#39;s IDE  1504  along with a prompt requesting that the consumer dial a toll free number from a landline-based telephone and then key in the numerical code  1506 . The consumer would then call the phone number and identify himself with the aforementioned unique code  1508 . The lottery computer would perform a reverse lookup on the Caller ID (CID) number to obtain location information  1510 . As in the case of cell towers and Wi-Fi access points, various service providers maintain a worldwide database of land line telephone numbers and addresses. This database can be licensed for a modest fee, allowing the lottery&#39;s application to determine if the consumer is within the lottery&#39;s legal boundaries. If the number is determined to be within the lottery&#39;s jurisdiction  1510 , there still remains the problem of a “spoofed” CID. The lottery will place a call-back to the CID number  1512  and if the call is not answered, the server will deny game play  1522 . If the call is answered and if the consumer enters the (correct) code at  1516 , game play is permitted. If no code or an incorrect code is entered  1516 , game play is denied  1522 . Numbers that cannot be identified (unknown)  1510  are typically cell phone numbers or Voice over Internet Protocol (VoIP) numbers and in some cases could be compared to data contained within a VoIP Location Information Server (LIS) database  1520 . If the VoIP or Cell number can be identified, it will cause a call back  1512  to prevent spoofing. Again, assuming the consumer answers the call  1514  and enters the numeric code  1516 , game play could be permitted  1518 . If the VoIP or Cell number cannot be confirmed  1520  or the consumer does not answer  1514  or an incorrect code is entered  1516  access to the game could be denied  1522 . 
     For those cases in which the consumer has not denied permission to forward RF receiver data—e.g., GPS, cell tower, or WPS data  1500  it may be that his game play IDE does not have access to RF receiver data. However, an alternate IDE may be available—e.g., the consumer may have a smart phone but does not wish to play the game on the small screen display— 1502 . In this case, a further level  5  option, the “Confirmation Code” option may be used  1524 . If another RF receiver is not available  1502 , a land-line option  1504  may be used. 
     As shown in  FIG. 16 , the lottery could offer a special purpose software application  1600  for a smart telephone or other IDE that would utilize the previously described location identification mechanism (e.g., GPS, cell tower triangulation, 802.11 triangulation, etc.) to locally authenticate that the IDE is in the lottery&#39;s jurisdiction. In one embodiment, the consumer would enter the SID code from the lottery&#39;s website (which could be provided upon acceptance of the GAC and would be displayed on the gameplay IDE) into the “secondary” IDE—i.e., the device being used for geolocation. The secondary IDE would then attempt to determine its location. Upon successful—i.e., in jurisdiction—location verification  1606 , the software would cryptographically create and display a Location Confirmation Code (LCC)  1608  on, for example, a pop-up window. The LCC could then be keyed-in to the gameplay IDE by the consumer  1610  when he is attempting to prove location to the lottery&#39;s Internet game web site. The lottery&#39;s server could create an LCC using the same input data and software routine  1614  that could be compared against the consumer&#39;s version  1616 . Ideally the LCC would be a short cryptographic code (e.g., keyed hash of current time, valid location, and SID) that would be accepted by the lottery&#39;s web site for some reasonable time after it was generated (say five minutes) and allow gaming to proceed without further interaction. Obviously, the LCC would be created using a method that was sufficiently hardened to avoid hacking of codes. If the two codes match  1616 , then game play can be allowed  1620  or prohibited  1618 . If the secondary IDE is found to be outside the lottery&#39;s jurisdiction  1606 , then game play would be denied  1618 . In the example described, the consumer does not divulge his actual location to the lottery. However other embodiments might send more precise information or longer LCCs depending upon specific requirements of the particular application. 
     Previous sections of this application have described geolocation for consumer Internet Devices that are involved in the playing of an Internet-based lottery type game. However, as will be appreciated by those skilled in the art, the same techniques may be useful for a variety of other purposes—e.g., to permit the online purchase and/or redemption of lottery tickets, geolocation of lottery terminals, geolocation of lottery ticket validation equipment, and other on-line commerce or logistics purposes. 
     Although preferred embodiments of the invention have been disclosed in the foregoing specification, it will be understood by those skilled in the art using the teachings disclosed herein that many modifications and other embodiments are within the scope of the present invention.

Technology Classification (CPC): 6