Abstract:
A proximity search engine for carrying out a proximity search with respect to a reference location uses as a reference frame the earth divided into tiles, which are predefined geographic regions of substantially equal areas. Records that are searched based on proximity to a reference location include location pointers, each of which identifies a particular tile that encompasses the physical location indicated by the corresponding record. When the proximity search is carried out, the tiles that are within a specified distance from the reference location are obtained and records having location pointers corresponding to such tiles are selected for inclusion in the search results.

Description:
BACKGROUND OF THE INVENTION  
       [0001]     1. Field of the Invention  
         [0002]     The present invention generally relates to proximity search techniques, and more specifically, to a method and a system for performing searches based on proximity to a reference location.  
         [0003]     2. Description of the Related Art  
         [0004]     A geographic location may be represented as latitude and longitude.  FIG. 1  illustrates a map of the world with latitude lines shown every 30 degrees and longitude lines shown every 30 degrees. The distance between any two points on the map shown in  FIG. 1  may be calculated based on their latitude and longitude positions, and the known radius of the earth (6371.01 km or 3958.76 miles).  
         [0005]     There are many ways of obtaining the latitude and longitude for a particular geographic location. Latitude and longitude positions for locations specified using zip codes, postal codes and cities may be obtained from third party databases using a simple table look-up. Also, a handheld electronic device, such as a pocket PC, cell phone or a personal digital assistant (PDA), may have a GPS receiver and associated software for determining the latitude and longitude position of the handheld electronic device.  
         [0006]     In the current art, a proximity search of database records with respect to a reference location is carried out by calculating the distances between the reference location and the locations associated with each of the database records. First, the latitude and longitude positions of the reference location are obtained. Second, the latitude and longitude positions of the locations associated with the database records are obtained. Third, the distances between the reference location and the locations associated with the database records are calculated. Fourth, the database records associated with locations that are within a certain distance (as specified in the proximity search request) from the reference location are selected to be included in the search results.  
         [0007]     When the number of database records is large, the proximity search method carried out in the above manner becomes computationally very expensive because of the large number of distance calculations that are required. Distance calculations that are based on zip codes and postal codes have been used to reduce the computational cost, but are not very accurate, and only work for locations in countries having postal codes that are mapped to latitude-longitude values. Quad trees and R-Trees that rely on a two-dimensional grid of regions and subregions have been used to describe the locations of objects in a two-dimensional space, but they require binary-like searches to zero in on the appropriate regions. For proximity searching, they are either too inaccurate (e.g., when the region size is large) or computationally too expensive (e.g., when the region size is sufficiently small).  
       SUMMARY OF THE INVENTION  
       [0008]     The invention provides an improved proximity search technique that is either faster or more accurate than the ones employed in the current art. According to the invention, the earth is divided into predefined geographic regions of substantially equal areas, referred to as tiles, and records that are searched based on proximity to a reference location include location pointers, each of which identifies a particular tile that encompasses the physical location indicated by the corresponding record. When the proximity search is carried out, the tiles that are within a specified distance from the reference location are obtained and records having location pointers corresponding to such tiles are selected for inclusion in the search results.  
         [0009]     The reference location may be specified in the proximity search as a zip code, city-state, or city-country, or the location of the user requesting the proximity search may be retrieved from a database as the reference location. If the user requesting the proximity search is carrying a handheld electronic device that includes a GPS receiver and associated software, the reference location may also be specified as the current location of the user as determined by the GPS receiver and associated software.  
         [0010]     After the reference location is determined, the latitude and longitude of the reference location are obtained and the tile that includes the latitude and longitude of the reference location is identified. The searched records that have location pointers that point to those tiles that are within the specified distance from the reference location tile are then selected for inclusion in the search results.  
         [0011]     Proximity searches carried out in the above manner no longer require individual distance calculations between the reference location and each database record being searched. As a result, the total number of distance calculations is reduced with the invention and the speed of the executed searches is increased. The invention also provides flexibility in designing proximity searches, e.g., the accuracy of proximity searches can be increased by decreasing the tile size and the speed of the proximity searches can be increased by increasing the tile size.  
     
    
     BRIEF DESCRIPTION OF THE DRAWINGS  
       [0012]     So that the manner in which the above recited features of the present invention can be understood in detail, a more particular description of the invention, briefly summarized above, may be had by reference to embodiments, some of which are illustrated in the appended drawings. It is to be noted, however, that the appended drawings illustrate only typical embodiments of this invention and are therefore not to be considered limiting of its scope, for the invention may admit to other equally effective embodiments.  
         [0013]      FIG. 1  is a map of the world illustrating latitude and longitude lines that uniquely identify a location on the map;  
         [0014]      FIG. 2  is a map of the world employing a coordinate system defining points that represent geographic regions having substantially the same area;  
         [0015]      FIG. 3  is a diagram illustrating the relationships between members in a social network;  
         [0016]      FIG. 4  is a block diagram illustrating a system for creating and managing an online social network;  
         [0017]      FIG. 5  shows a simplified user interface with which a new record is entered into a database;  
         [0018]      FIG. 6  is a flow diagram illustrating how a location pointer is obtained for the new record entered in  FIG. 5 ;  
         [0019]      FIG. 7  illustrates a database containing records having location information;  
         [0020]      FIG. 8  shows an input interface for specifying a search query that includes a proximity criteria; and  
         [0021]      FIG. 9  is a flow diagram illustrating how search results that are responsive to the search query of  FIG. 8  are obtained.  
     
    
     DETAILED DESCRIPTION  
       [0022]     Each geographic location in  FIG. 1 , which can be represented as latitude and longitude, may be mapped onto a point in  FIG. 2 . In fact, the map of  FIG. 1  is divided into a plurality predefined geographical regions or areas, referred to as tiles, and all points contained in one tile map onto a single point in  FIG. 2 . A tile can have any configuration, but in the embodiment of the invention described herein, each such tile covers roughly the same area in  FIG. 1  and all four sides of each such tile have the same fixed length. The formulas used for mapping a location in  FIG. 1  that is defined by latitude and longitude onto a point in  FIG. 2  are as follows: 
 
LatQ=Int(latitude+90)* k/r+ 1); and 
 
LongQ=Int(longitude+180)* k  Cos (latitude/ r+ 1), 
 
 where latitude and longitude values are expressed in degrees; k is a factor for converting a 1-degree arc measured with respect to earth&#39;s center into miles (k=2π*(earth&#39;s radius)/360°=69.0933 miles/degree); r is the length of each side of a tile (in the illustrated embodiment, r=3.4 miles); and LatQ and LongQ define the position of a tile in the coordinate system shown in  FIG. 2 . 
 
         [0023]     The LatQ value defines the position of the tile along the x-axis, beginning with LatQ=1, and the LongQ value defines the position of the tile along the y-axis, beginning with LongQ=1. The north pole in  FIG. 1  is mapped onto a point at the upper tip of the triangle in  FIG. 2  represented by (LatQ=3658, LongQ=1) and the south pole in  FIG. 1  is mapped onto a point at the lower tip of the triangle in  FIG. 2  represented by (LatQ=1, LongQ=1). The equator, represented by (LatQ=1829, 1&lt;LongQ&lt;7316), maps onto a line that cuts through the center of the triangle in  FIG. 2  and divides it into an upper half (northern hemisphere) and a lower half (southern hemisphere). The right tip of the triangle in  FIG. 2  represents the (LatQ, LongQ) pair corresponding to the tile that contains the equator at the international date line (longitude: 180° E or 180° W).  
         [0024]     The international date line maps onto a line that is shown in  FIG. 2  as the left side of the triangle. All other equilongitude lines (i.e., a line connecting points having the same longitude) map onto a pair of lines, the first originating from the north pole (LatQ=3658, LongQ=1) to a point along the equator and the second originating from the south pole (LatQ=1, LongQ=1) to the same point along the equator. The upper and lower sides of the triangle in  FIG. 2  represent the international date line that is approached when moving west to east.  
         [0025]     The invention will now be described in the context of a social network. A social network is generally defined by the relationships among groups of individuals, and may include relationships ranging from casual acquaintances to close familial bonds. A social network may be represented using a graph structure. Each node of the graph corresponds to a member of the social network. Edges connecting two nodes represent a relationship between two individuals. In addition, the degree of separation between any two nodes is defined as the minimum number of hops required to traverse the graph from one node to the other. A degree of separation between two members is a measure of relatedness between the two members.  
         [0026]      FIG. 3  illustrates a graph representation of a social network centered on a given individual (ME). Other members of this social network include A-U whose position, relative to ME&#39;s, is referred to by the degree of separation between ME and each other member. Friends of ME, which includes A, B, and C, are separated from ME by one degree of separation (1 d/s). A friend of a friend of ME is separated from ME by 2 d/s. As shown, D, E, F and G are each separated from ME by 2 d/s. A friend of a friend of a friend of ME is separated from ME by 3 d/s.  FIG. 1  depicts all nodes separated from ME by more than 3 degrees of separation as belonging to the category ALL.  
         [0027]     Degrees of separation in a social network are defined relative to an individual. For example, in ME&#39;s social network, H and ME are separated by 2 d/s, whereas in G&#39;s social network, H and G are separated by only 1 d/s. Accordingly, each individual will have their own set of first, second and third degree relationships.  
         [0028]     As those skilled in the art understand, an individual&#39;s social network may be extended to include nodes to an Nth degree of separation. As the number of degrees increases beyond three, however, the number of nodes typically grows at an explosive rate and quickly begins to mirror the ALL set.  
         [0029]      FIG. 4  is a block diagram illustrating a system for creating and managing an online social network. As shown,  FIG. 4  illustrates a system  100 , including an application server  200  and graph servers  300 . The computers of system  100  are connected by a network  400 , e.g., the Internet, and accessible by over the network by a plurality of computers, collectively designated as  500 . The application server  200  manages a member database  210 , a relationship database  220 , and a search database  230 .  
         [0030]     The member database  210  contains profile information for each of the members in the online social network managed by the system  100 . The profile information may include, among other things: a unique member identifier, name, age, gender, location, hometown, references to image files, listing of interests, attributes, and the like. The location information may include: (i) address, city, state, zip code or postal code, and country; (ii) latitude and longitude values associated with the specified address, zip code, postal code, city-state or city-country; and (iii) a pointer to a tile that includes the location associated with the latitude and longitude values. The relationship database  220  stores information defining to the first degree relationships between members. The relationship database  220  stores information relating to the first degree relationships between members. In addition, the contents of the member database  210  are indexed and optimized for search, and stored in the search database  230 . The member database  210 , the relationship database  220 , and the search database  230  are updated to reflect inputs of new member information and edits of existing member information that are made through the computers  500 .  
         [0031]     The application server  200  also manages the information exchange requests that it receives from the remote computers  500 . The graph servers  300  receive a query from the application server  200 , process the query and return the query results to the application server  200 . Graph servers  300  store a graph representation of the social network defined by all of the members (nodes) and their corresponding relationships (edges). The graph servers  300  respond to requests from application server  200  to identify relationships and the degree of separation between members of the online social network.  
         [0032]     The application server  200  is further configured to query a third party service  600  for latitude and longitude values corresponding to location information (e.g., address, zip code, postal code, city-state, city-country, etc.) that it sends as a part of the query. The third party service  600  looks up the latitude and longitude values corresponding to the location specified in the query from its database  610  and returns the latitude and longitude values to the application server  200 . In an alternative embodiment, the database containing latitude and longitude values corresponding to locations specified in terms of address, zip code, postal code, city-state, and/or city-country, may be maintained as part of the computer system  100  and accessed internally by the application server  200 .  
         [0033]      FIG. 5  shows a simplified user interface with which a new record is entered into the member database  210 . The inputs include location information such as the address, city, state and zip code. Persons not living in the U.S. will enter country information in place of state and postal code information instead of zip code.  
         [0034]      FIG. 6  is a flow diagram illustrating how a location pointer is obtained for a new record and stored in the member database  210 . In Step  601 , user inputs, e.g., those made with the user interface of  FIG. 5 , are received by the computer system  100  and stored in the member database  210 . In Step  602 , the computer system  100  queries a third party service  600  for latitude and longitude values corresponding to the location information associated with the new record and receives them from the third party service  600 . The location parameters that are passed to the third party service  600  may be address, city, state, country, zip code, postal code, or any combination of the foregoing. The third party service  600  looks up the latitude and longitude values corresponding to the location parameters and returns them to the computer system  100 . In an alternative embodiment, the latitude and longitude look up is not performed by the third party service  600 , but by the computer system  100 .  
         [0035]     In Step  603 , the latitude and longitude values are used to calculate corresponding LatQ and LongQ values using the following formula: 
 
LatQ=Int((latitude+90)* k/r+ 1); and 
 
LongQ=Int((longitude+180)* k * Cos (latitude)/ r+ 1). 
 
 where k is a factor for converting a 1-degree arc measured with respect to earth&#39;s center into miles (k=2π*(earth&#39;s radius)/360°=69.0933 miles/degree); r is the length of the sides of the tiles and is 3.4 miles; and latitude and longitude values are expressed in degrees. Accuracy in the proximity searches can be improved by reducing r, but at the expense of computational speed. Computation speed of the proximity searches can be increased by increasing r, but at the expense of accuracy. 
 
         [0036]     In Step  604 , the (LatQ, LongQ) pair is stored in the member database  210  as part of the new record and is used as a pointer to identify the particular tile that covers the location associated with the new record. To optimize for database indexing, the (LatQ, LongQ) pair may be packed into a single integer value.  
         [0037]      FIG. 7  illustrates a member database  210  containing location information. It shows the location information for records ME, A, B, C, and U, and the corresponding latitude and longitude values. Each record also has a pointer (x, y) that identifies the particular tile that covers the location associated with such record. Each of these pointers was derived in the manner illustrated in  FIG. 6  when its corresponding record was entered into the database as a new record. For example, the record ME has a zip code 94087 which, according to a latitude and longitude look-up service, is located at 37.40 N latitude and 122.00 W longitude, and this location maps onto a tile that is located at point (x=2589, y=937).  
         [0038]      FIG. 8  shows a sample input interface for specifying a search query that includes a proximity criterion. The input parameter “Your Location” defaults to the zip code of the person who is requesting this search, but it may be changed by the user if the user desires to perform the proximity search with respect to a different zip code. If the search query is being entered using a handheld electronic device that includes a GPS receiver and associated software that automatically determines the latitude and longitude values associated with the current location of the handheld electronic device, and the user desires to perform the proximity search based on the GPS-determined location, the user leaves the “Your Location” field blank, and the latitude and longitude values determined by the GPS receiver and associated software appears in the corresponding “Latitude” and “Longitude” fields and are passed as part of the search query. The location specified in the “Your Location” field or the GPS-determined location represents the reference location from which the proximity search will be carried out.  
         [0039]     The input parameter “Proximity” defines the distance value that is used in carrying out the proximity search. A distance value of 25 miles, as illustrated in  FIG. 8 , means that the proximity search will be carried out for all records having associated locations that are within 25 miles of the reference location. Other input parameters may be specified in conducting a proximity search (e.g., keywords, gender preference, marital status, etc.), but for simplicity, are not illustrated here. Also, the invention is applicable to any type of proximity searches, and not limited to proximity searches for members within a social network.  
         [0040]      FIG. 9  is a flow diagram illustrating how search results that are responsive to the search query are obtained. In Step  901 , the proximity search parameters, e.g., those made with the user interface of  FIG. 8 , are received by the computer system  100 . In Step  902 , a decision is made as to whether latitude and longitude values are passed as part of the search query. If not, the reference location information, e.g., zip code, is passed to the third party service  600 , and the third party service  600  looks up the latitude and longitude values corresponding to the reference location information and returns them to the computer system  100  (Step  903 ). In an alternative embodiment, the latitude and longitude look up is not performed by the third party service  600 , but by the computer system  100 . Flow then proceeds to Step  904 .  
         [0041]     If the latitude and longitude values are passed as part of the search query, Step  903  is skipped and flow proceeds directly to Step  904 . In Step  904 , a set of (LatQ, LongQ) values that correspond to the longitude of the reference location and are within the specified distance from the reference location is obtained. In Step  905 , for each (LatQ, LongQ) value in the set obtained in Step  904 , all LongQ values that are within the specified distance directly to the west and directly to the east (i.e., to the west and to the east along the same latitude) are obtained. In Step  906 , all (LatQ, LongQ) values obtained in Step  905  are compiled into an array as valid location pointers. In Step  907 , if any records in the database have (LatQ, LongQ) values that are contained in the array of valid location pointers, these records are included in the search results.  
         [0042]     The code that implements Steps  904 - 906  of  FIG. 9  is reproduced below: 
    Range=Round((Distance−(r/2.0))/r); //r=3.4 miles, as specified before;     Distance represents the distance value that is specified in the search query;    
 
         [0045]     Round represents an integer operation of rounding up  
                                                                       for (i = −Range; i &lt;=Range; i++) {                midBoxLat = latitude + i * r / k; // latitude is the latitude of           the reference location; k is the factor for converting 1 degree of           latitude into miles and equals 69.0933 miles/degree           midBoxLatQ = Int((midBoxLat + 90)*k/r+1);           midBoxLonQ = Int((longitude+180)*k*Cos(midBoxLat)/r+1); //           longitude is the longitude of the reference location           for (j = midBoxLonQ − Range; j &lt;= midBoxLonQ +Range; j++) {                list.add((midBoxLatQ | j);                }            }                  
 
         [0046]     While particular embodiments according to the invention have been illustrated and described above, those skilled in the art understand that the invention can take a variety of forms and embodiments within the scope of the appended claims.