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  • G06F16/00—Information retrieval; Database structures therefor; File system structures therefor
  • G06F16/20—Information retrieval; Database structures therefor; File system structures therefor of structured data, e.g. relational data
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  • G06F16/20—Information retrieval; Database structures therefor; File system structures therefor of structured data, e.g. relational data
  • G06F16/24—Querying
  • G06F16/245—Query processing
  • G06F16/2457—Query processing with adaptation to user needs
  • G06F16/24578—Query processing with adaptation to user needs using ranking
• • G—PHYSICS
  • G06—COMPUTING; CALCULATING OR COUNTING
  • G06F—ELECTRIC DIGITAL DATA PROCESSING
  • G06F16/00—Information retrieval; Database structures therefor; File system structures therefor
  • G06F16/20—Information retrieval; Database structures therefor; File system structures therefor of structured data, e.g. relational data
  • G06F16/24—Querying
  • G06F16/248—Presentation of query results
• • G—PHYSICS
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  • G06F—ELECTRIC DIGITAL DATA PROCESSING
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  • G06F16/20—Information retrieval; Database structures therefor; File system structures therefor of structured data, e.g. relational data
  • G06F16/28—Databases characterised by their database models, e.g. relational or object models
  • G06F16/284—Relational databases
  • G06F16/288—Entity relationship models
• • G—PHYSICS
  • G06—COMPUTING; CALCULATING OR COUNTING
  • G06F—ELECTRIC DIGITAL DATA PROCESSING
  • G06F16/00—Information retrieval; Database structures therefor; File system structures therefor
  • G06F16/40—Information retrieval; Database structures therefor; File system structures therefor of multimedia data, e.g. slideshows comprising image and additional audio data
  • G06F16/44—Browsing; Visualisation therefor
  • G06F16/444—Spatial browsing, e.g. 2D maps, 3D or virtual spaces
• • G—PHYSICS
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  • G06F17/00—Digital computing or data processing equipment or methods, specially adapted for specific functions
  • G06F17/40—Data acquisition and logging
• • G—PHYSICS
  • G06—COMPUTING; CALCULATING OR COUNTING
  • G06Q—INFORMATION AND COMMUNICATION TECHNOLOGY [ICT] SPECIALLY ADAPTED FOR ADMINISTRATIVE, COMMERCIAL, FINANCIAL, MANAGERIAL OR SUPERVISORY PURPOSES; SYSTEMS OR METHODS SPECIALLY ADAPTED FOR ADMINISTRATIVE, COMMERCIAL, FINANCIAL, MANAGERIAL OR SUPERVISORY PURPOSES, NOT OTHERWISE PROVIDED FOR
  • G06Q30/00—Commerce
  • G06Q30/02—Marketing; Price estimation or determination; Fundraising
  • G06Q30/0201—Market modelling; Market analysis; Collecting market data
  • G06Q30/0204—Market segmentation
  • G06Q30/0205—Location or geographical consideration
• • G—PHYSICS
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  • G06Q—INFORMATION AND COMMUNICATION TECHNOLOGY [ICT] SPECIALLY ADAPTED FOR ADMINISTRATIVE, COMMERCIAL, FINANCIAL, MANAGERIAL OR SUPERVISORY PURPOSES; SYSTEMS OR METHODS SPECIALLY ADAPTED FOR ADMINISTRATIVE, COMMERCIAL, FINANCIAL, MANAGERIAL OR SUPERVISORY PURPOSES, NOT OTHERWISE PROVIDED FOR
  • G06Q30/00—Commerce
  • G06Q30/02—Marketing; Price estimation or determination; Fundraising
  • G06Q30/0241—Advertisements
  • G06Q30/0251—Targeted advertisements
  • G06Q30/0261—Targeted advertisements based on user location

Definitions

• the invention relates to mapping systems, and more particularly, to techniques for prioritizing geographical entities for placement on geographical displays.
• GIS geographic information system
• the system generally can utilize a variety of data types, such as imagery, maps, and tables.
• GIS technology has been used for scientific and governmental investigations (e.g., to identify geographical areas adversely impacted by pollution or over-building), resource management (e.g., regional forestry observation), and development planning (e.g., suburban development of under-utilized geographic areas).
• placemarks e.g., designated on the map with an icon or other graphic.
• placemarks allow the user to write a brief description relevant to the location marked by the placemark, while other placemarks allow the user to change the style of icons and/or labels associated with the placemark.
• the number of available placemarks is significant.
• a geographic information system comprises information about a plurality of geospatial entities and is configured to prioritize the geospatial entities according to a ranking mechanism.
• the ranking mechanism uses data about a meta attribute of a geospatial entity to determine the geospatial entity's priority.
• the meta attribute may vary in different implementations but in one embodiment comprises the quality of information available about a geospatial entity.
• a computer-implemented method can be used to rank geospatial entities.
• the method comprises several steps including receiving geospatial entity data, evaluating attributes of geospatial entities included in the received geospatial entity data, ranking the geospatial entities based on the evaluation, and storing the ranked geospatial entity data.
• Another embodiment of the present invention provides one or more machine-readable mediums (e.g., one or more compact disks, diskettes, servers, memory sticks, or hard drives) encoded with instructions, that when executed by one or more processors, cause the one or more processors to carry out a process for ranking geospatial entities.
• This process can be, for example, similar to or a variation of the methodologies described herein.
• FIG. 1 is a block diagram of a GIS system with entity ranking capabilities in accordance with an embodiment of the invention.
• FIG. 2 is a block diagram of the entity ranking module shown in FIG. 1 , according to one embodiment of the present invention.
• FIG. 3 illustrates a method for generating and providing prioritized entities in accordance with an embodiment of the invention.
• FIG. 4 illustrates a method for requesting and receiving a map including prioritized placemarks in accordance with an embodiment of the invention.
• FIG. 5 depicts a GIS map that includes prioritized placemarks in accordance with an embodiment of the invention.
• GIS geographic information system
• DGIS distributed geographic information system
• some interactive Geographic Information Systems support different feature visibility criteria at different viewing distances. For example, a selection criteria might be constructed that would show only cities exceeding one million in population when the view was of the North American continent (viewing distance 1), then include additional cities exceeding 100,000 in population when the viewpoint is lowered to include a single state in the display area (viewing distance 2), and finally modified to include smaller cities as the view lowers within a state or county (viewing distance 3).
• selection criteria might be constructed that would show only cities exceeding one million in population when the view was of the North American continent (viewing distance 1), then include additional cities exceeding 100,000 in population when the viewpoint is lowered to include a single state in the display area (viewing distance 2), and finally modified to include smaller cities as the view lowers within a state or county (viewing distance 3).
• An embodiment of the present invention is configured to determine ‘which few of many’ geospatial items or entities to display on a map according to the relative importance of each entity according to its rank.
• a rank can be generated based on extrinsic factors, such as the popularity of the entity to users (e.g., quantity and/or velocity of geospatial item access), quality of information (e.g., respect for the information source of geospatial item and community stature of geospatial item's author), and similar meta-data about the geospatial feature.
• an embodiment of the present invention would be to give that city a sufficiently significant place rank for display so as to display it along with the major cities exceeding one million in population.
• users are shown the geospatial entities most likely to be of interest in the area of their visual search within an interactive geospatial information system.
• the ranking of geospatial items may further be based on location, distance, or other intrinsic attributes of a geospatial feature such as position and altitude (zoom level).
• ranked entity data generated in accordance with an embodiment of the present invention may be supplied to various systems in addition to or instead of a digital mapping system as required by the context.
• a two or three-dimensional digital map can be generated that includes placemarks that correspond to geospatial entities.
• a map generated by a GIS may include several types of data about geospatial entities.
• the map may include geographic features such as the terrain, infrastructure including roads, rail routes and airports, buildings, and/or borders of a landscape.
• the map may also be annotated with information about government entities and services such as parks and recreational services, federal, state, or local government landmarks, and community services.
• placemarks belonging to one or more categories including commercial placemarks that represent businesses, travel placemarks including, for instance, historical sights and tourism destinations, user-defined placemarks that have been identified and named by a user for personal or community use, and/or community placemarks that have been voluntarily defined by members of the public in a forum.
• information presented on a map is organized into collections that comprise layers, such as a terrain layer, road layer, border layer, community placemark layer, etc. Other layers include ‘current events’, ‘history’, and ‘education’, and indicate the organizational taxonomy of the source from which they were taken.
• a user can interact with a map and turn on or off various layers of information.
• a basic or core layer includes a basic subset of data (for instance, the terrain, major roads, and political borders), and the user can select additional layers to customize the map view.
• Various third-party content-providers and advertisers can provide individual layers of data that can be overlaid onto such a basic map.
• the placemark ranking methods described herein can be used in combination with any conventional, proprietary, and/or emerging techniques to generate a digital map.
• a conventional raster map for instance, the placemarks and other types of map data are used to create a map in a digital format such as .jpeg, .gif, or .png, at a map server and then delivered to a client. Requests to manipulate or interact with the map, are provided from the client to the server, which in turn generates the requested map view.
• pre-generated, rasterized images or “tiles” that include placemark data are stored at a map server.
• map data including placemark data
• map server in the form of vector graphic instructions.
• the instructions are interpreted by an application at the client in real-time to generate a map for the user.
• the map can be dynamically updated at the client to include those layers.
• the map can be dynamically regenerated at the client to include the new map views.
• GIS Geographic information systems
• a GIS may be implemented as a distributed geographic information system (DGIS), in which, for instance, GIS components are distributed across two or more different computers in different physical locations across a network such as the Internet or a corporate enterprise.
• DGIS distributed geographic information system
• Google Earth a GIS-based digital globe that includes various elements such as servers, clients, and other components and features as will be apparent in light of this disclosure.
• Google Earth Community a forum in which placemarks and entities are created, defined, described, and discussed by members of the participating public. Note that “Google Earth” and “Google Earth Community” and the descriptions provided herein may be protected under other forms of intellectual property, and are used for reference purposes only.
• FIG. 1 is a high-level diagram of a digital map system 100 with entity ranking capabilities in accordance with an embodiment of the invention.
• the system 100 includes a map server system 150 that is communicatively coupled to one or more clients 110 via a network 160 .
• the map server system 150 is coupled to a database 140 of ranked entity data populated (e.g., offline, or in real-time) by a GIS 170 .
• the GIS 170 is equipped with an entity ranking module 120 A that applies a ranking mechanism or algorithm to determine the relative ranks of geospatial entities. These entities may be defined within the GIS 170 , for instance, based on data provided to the GIS 170 from various external sources 180 .
• the ranked entities are stored in a database 140 and supplied to the map server system 150 , which uses the ranked entity data to generate maps for clients 110 .
• client-side entity ranking modules 120 B-C are also present for providing additional entity ranking functionality.
• the map server system 150 may provide the ranked entity data to clients 110 for client-side generation of maps and ranked entity data layers. Principles of heavy-client and light-client functionality equally apply here, as will be apparent in light of this disclosure.
• modules may be included in the system, and illustrated modules may be rearranged and functionalities can be distributed.
• the GIS 170 can be integrated into the map server system 150 .
• the entity ranking module 120 A of the GIS may be a standalone module. There may be a single entity ranking module 120 A implemented wholly in or with the GIS system 100 , without any entity ranking modules 120 B-C on the client side 110 . In another embodiment, entity ranking is implemented strictly by entity ranking modules 120 B-C at clients 110 .
• the term “module” refers to computer program logic or software for providing the specified functionality.
• a module When utilized by a client device 120 or map server system 150 , a module may be loaded into memory and executed on a processor.
• a module can be implemented in hardware (e.g., gate-level logic), firmware (e.g., a microcontroller with embedded routines for carrying out entity ranking as discussed herein), software, or some combination of hardware, firmware, and/or software.
• the client 110 can be any device that allows a user to access the map server system 150 via the network 160 .
• the client 110 may a device or system configured for computing, such as a personal computer or laptop, a mobile phone, a personal digital assistant, a smartphone, a navigation system located in a vehicle, or a handheld GPS system.
• Other clients 110 may also be in communication with the map server system 150 via the network 160 .
• Each client 110 includes an application such as a browser that allows the user to interface and communicate with systems such as the map server system 150 on the network 160 , as typically done.
• Examples of browsers include Microsoft's Internet Explorer browser, Netscape's Navigator browser, Mozilla's Firefox browser, PalmSource's Web Browser, or any other browsing or application software capable of communicating with network 160 .
• the client 110 may include an application implemented outside of a browser, such as a specialized mapping or geographic application, from which data on the map server system 150 can be accessed. Interactions with the map server system 150 may be accomplished through a plug-in or other executable architecture implemented locally.
• the GIS 170 can be configured with conventional technology, but further includes an entity ranking module 120 A configured in accordance with the principles of the present invention.
• the GIS 170 receives data from various sources 180 upon which ranked entity data can be determined by the entity ranking module 120 A. Both geospatial entities and ranking data by which the geospatial entities can be ranked are represented in the data. These types of data can be provided to the GIS 170 in structured and unstructured form. For instance, while entity data in the form of city names and geographies may be provided in a structured form, ranking data in the form of community comments or ratings, for instance, may be provided in unstructured form. Or, entity data and ranking data may be provided from the same structured source that, for example, identifies a city and its population, or an unstructured source such as a community bulletin board in which an entity is defined and data by which it can be ranked is provided.
• the entity ranking capability of the map system 100 is provided by one or more entity ranking modules 120 .
• the entity ranking module 120 collects entity data and ranking data with which the geospatial entities can be rated. This data may be provided from various sources including the GIS 170 , external sources 180 , and the client 110 . These sources are described in further detail with reference to FIG. 2 .
• the module 120 evaluates the geospatial entities using the ranking data in order to determine a score or rank for each of the entities.
• the module 120 also associates the entities with placemarks for a map, and generates groupings or layers of placemarks based on, for instance, a certain placemark density or map view altitude.
• the resulting entities and entity layers can be stored in a ranked entity database 140 , at a client 110 , or elsewhere. Each of these capabilities will be described in further detail with reference to FIG. 2 .
• the client-side modules 120 B-C may provide complementary rankings for use in generating a map for a client 110 .
• a server-side entity ranking module 120 A provides general placemarks whose rank is determined by a set of general ranking data
• a client-side entity ranking module 120 B-C provides personal placemarks that have been ranked using personal data about a user, their behavior, or their preferences.
• the network 160 may be any type of communications network, such as a local area network (e.g., intranet), wide area network (e.g., internet), or some combination thereof.
• the network 160 may be a direct connection between the client 110 and the map server system 150 .
• the client 110 , network 160 , and/or map server system 150 may be in communication via any type of wired or wireless connection, using a wide variety of communication protocols.
• the map server system 150 can be implemented with conventional or custom technology. Numerous known server architecture and functionalities can be used to implement a GIS server system. Further, the map server system 150 may include one or more servers operating under a load balancing scheme, with each server (or a combination of servers) configured to respond to and interact with clients 110 via the network 160 . In one particular embodiment, the server system 150 is implemented as discussed in U.S. application Ser. No. 10/270,272, filed Oct. 10, 2002, titled “Server for Geospatially Organized Flat File Data,” which is incorporated herein.
• a user of a client computer 110 enters a search query (e.g., via browser and client side agent), it is put into a request by the client 110 , and sent to the map server system 150 via the network 160 .
• the server system 160 determines what the search query is for, and responds with appropriate data from various sub-systems, such as geo-coders, routing engines, and local search indexes, in a format that the requesting client can use to present the data to the user (e.g., via a browser or other application).
• the GIS 170 and ranked entity database 140 provide a map system 100 that serves map and GIS data over the Internet or other network 160 .
• the map system 100 allows users to visualize, select, and explore geographic information (e.g., all over the world or in a particular region).
• the entity ranking module 120 A can be configured to place rank available map data items based on various attributes associated with each geospatial feature (or a subdsdscset of geospatial features). These attributes may be extrinsic or instrinsic attributes of a geospatial feature, represent meta attributes of the feature, and/or reflect the personal behavior of a user. Based on ranking entities according to these attributes, users are shown the geospatial entities most likely to be of interest in the area of their visual search within the interactive GIS.
• FIG. 2 is a high-level block diagram of an entity ranking module 120 that could be implemented at a client computer or server-side GIS according to one embodiment of the present invention.
• the entity ranking module 120 receives or collects data from various sources about geospatial entities through an interface 250 .
• the data contains both entity data 210 that identifies and defines geospatial entities and ranking data 220 by which geospatial entities can be evaluated.
• the entity data 210 may comprise placemark-level data.
• the ranking engine 230 applies one or more ranking algorithms or rank mechanisms to the ranking data 220 to determine scores for geospatial entities defined in the entity data 210 .
• the resulting ranked entity data may be provided through the interface 250 to a requesting application such as a mapping application.
• the ranked entity data can be formed into placemark layers by a placemark layer generator 240 .
• the ranked entity data is stored and provided to a map server system or other application.
• the entity ranking module 120 includes a memory 260 in which data collected, including from a client, can be stored.
• the entity ranking module 120 can receive entity data 210 and ranking data 220 about entities from any number of sources.
• the data may include satellite data, aerial photographs, street-level photographs, digital map data, tabular data (e.g., digital yellow and white pages), and targeted database data (e.g., databases of diners, restaurants, museums, and/or schools; databases of seismic activity; database of national monuments; etc). It may also include government census and population data, building plan data, demographic data including socio-economic attributes associated with a geospatial entity such as a zip code or town, and alternative name data.
• the data comprises proprietary content collected by a third-party provider and placemarks derived from it can only be accessed by users who have specifically paid for or subscribed to it.
• geospatial entities 210 and ranking data 220 in the form of information about attributes of geospatial entities may also be provided in unstructured form.
• data can be harvested from websites on the internet, and/or culled or provided from various sources including community forums such as the Google Earth Community, online bulletin boards, or other virtual spaces in which geospatial entities may be defined and described by users in a public, private, or semi-public setting.
• community forums such as the Google Earth Community, online bulletin boards, or other virtual spaces in which geospatial entities may be defined and described by users in a public, private, or semi-public setting.
• the entity ranking module 120 may also receive data from one or more clients 110 that may be particular to a user or client device 110 . As described in more detail below, this data can be used to customize rankings and/or a user's experience.
• Example geospatial entities include a city name and location, a user defined entity, a commercial entity, a geospatial item found in a web search, or any item (e.g., physical thing, event, or quality) having a geographic association.
• a geospatial entity is thus comprised of a geometry associated with a physical place (such as a set of geographic coordinates on Earth or the moon) and a description.
• this geometry may correspond to locations associated with the event.
• the entity can correspond to single or multiple physical places and descriptions.
• geospatial entities in Google Earth can be either singleton objects or may be a hierarchical folder of objects, each object in which may be another folder or an entity.
• a single entity may correspond to one or more placemarks.
• an entity like “Oakland gas stations” may include several different physical locations, each of which is represented by a separate placemark.
• Ranking data 220 may describe attributes of entities that can be evaluated by the ranking engine 230 to determine the entity's rank.
• the attribute defines the interestingness of an entity to a particular user. Such interestingness can be used to rank the various geospatial entities in the area of a user's visual search within an interactive geospatial information system (such as Google Earth), so that client-side entity display prioritizing is enabled.
• “interestingness” for a geospatial entity can be determined by measuring or otherwise determining various types of extrinsic data associated with that entity. In one such embodiment, this measure, scaled by a corresponding weight, forms a bonus that augments the entity's score or rank (e.g., by addition or multiplication). Thus, higher ranked entities can be given priority for display over lower ranked (less interesting) entities.
• Data intrinsic to the GIS system may also be considered, as normally done (e.g., zoom level).
• ranking data 220 comprises various indications of a user's interest in certain placemarks. For instance, placemarks that have been saved or annotated by the user at the browser or application level could be deemed to be of greater interest to a user.
• a user's search terms or patterns of web page access or use may also be correlated to certain geospatial entities and used by an entity ranking module 120 at the client or on a server to select placemarks for the user.
• placemarks that the user has defined for his or her own use may be assumed to be of high personal interest.
• geospatial entities including points of interest or personal relevance to the user, such as the location of the user's house, workplace, child's daycare, or favorite playground are identified and marked on any map in the vicinity of these elements, regardless of their relative rank as calculated by a GIS.
• These and other indications of user interest may be gauged from the user's behavior, or may be in the form of preferences or instructions regarding entities affirmatively provided by the user, for instance instructing the inclusion or exclusion of specific entities or groups of entities in maps provided by a map server system.
• a rankings premium may be assigned to geospatial entities based on the user's interest or preferences.
• User data collected at a client may be stored in the memory 260 of the entity ranking module and used by the ranking engine 230 to generate entity rankings that are personal to the user.
• the ranking engine 230 comprises a module for ranking entities based on descriptions of entity attributes included in the ranking data 220 . Depending on the type of data provided, the ranking engine 230 can use a variety of mechanisms to evaluate geospatial entities, which are further described below.
• the entities as ranked by the ranking engine 230 are organized into layers by a placemark layer generator 240 . This may be accomplished by determining a level of detail and threshold to be associated, for instance, with a given altitude or density. For instance, when a user's query implicates a number of entities greater than a given threshold, only those entities having a place rank above a certain threshold are provided. For example, assume the given threshold for the total number of entities that can be displayed at the current map view is 50, and that the place rank threshold is 80. If a user's query implicates over 100 geospatial entities, and 35 entities have a place rank over 80, then the server system will serve those 35 entities along with the 15 next highest ranked entities for display at the requesting client.
• a client-side entity ranking module 120 which then determines which of those entities to display (in a similar fashion to the server-side functionality).
• server-side and client-side entity ranking can be carried out, where the server system serves a set of ranked entities, and a client then displays a sub-set of that served set.
• Placemarks can be subdivided into layers according to criteria other than altitude or density, including conceptual, spatial, temporal, or other groupings.
• the placemark layer generator also applies stylings to the various placemarks and stores those with the placemark layers.
• One embodiment of the present invention is a method for computing a relative ranking of a geospatial entity such as a city name and location, user defined entity, commercial entity, or geospatial item found in a web search, as compared to other such entities.
• These relative rankings are determined by a ranking engine 230 and are used within a GIS (e.g., as discussed with reference to client-side entity ranking of FIG. 1 ) to order the display of entities when not all can be selected for display, for example, to show some of the highest or lowest ranked entities, or perhaps a selected range of entities.
• this ranking which can be referred to as place rank, is computed based on the weighted contributions of various non-cartographic meta attributes about a geospatial entity. Rather than directly measuring a characteristic of a physical place, such as its population, these attributes reflect traits of abstractions or representations associated with the geospatial entity. Examples include an attribute of a description of an entity (for instance, the amount of detail in the description of an entity or the number of times a description has been viewed), an attribute of a definition of an entity (e.g.
• One or more of the attributes listed above is evaluated and the results are weighted individually with a scale factor before being summed to produce an overall score for an entity. Such a calculation could be performed by the ranking engine depicted in FIG. 2 .
• both meta attribute data about a geospatial entity and data that reflects attributes of the entity itself are used to determine the overall score. For instance, in an embodiment, the size of a business and the number of replies to a posting about the business are both factors that are weighed by a ranking engine 230 . The ordering of entities by non-increasing score defines the ranking (descending order).
• the weighting factors can be changed based on resulting rankings to adjust the relative prominence of each attribute (e.g., automatically, or as desired by the system administrator, or by an individual user).
• an end user can assign the weights to be applied to each type of attribute. Any of the weightings can be set to zero (or one in the case of relative importance) to remove that attribute from consideration or equivalently some of the attributes may be ignored.
• the weighting factors can be made negative to downgrade rather than reward entities for a particular attribute. Applying scale factors to individual attributes allows diverse attributes to be evaluated and a total score to be calculated based on the attributes.
• SCORE NumberOfPostCharacters+a*NumberOfDescriptionCharacters)+b*NumberOfReplies+c*NumberOfViews+d*NumberOfDownloads+StatureWithinCommunity, wherein a, b, c, and d represent variables that can be adjusted based on the value assigned to each attribute.
• the StatureWithinCommunity reflects the poster of a description, and, in an embodiment, can range from 200 to 500 depending on the poster's stature based on any of a number of criteria including reputation, posting behavior, and ratings or endorsements by other users.
• One embodiment of the ranking system described herein aggregates the individual attribute measures with a general linear combination.
• a more sophisticated aggregation, of which the linear combination is the subset along the main diagonal, is to use an M by M matrix of weights, where the dimension M corresponds to the number of attributes, and matrix reduction is used to allow specification of weights for the full cross product of attributes. For example, such a technique allows a specified weight for the product of ‘description length’ and ‘author stature’ as a combined component.
• the two equation structures described herein are representative of the variety of attribute combination methods that will be apparent in light of this disclosure, such as including exponentiation or other algebraic forms in the evaluation of each attribute.
• extrinsic meta data about a geospatial entity can be used as input to a scoring system that produces a relative ranking for purposes such as selection for display within a geospatial information system.
• a scoring system that produces a relative ranking for purposes such as selection for display within a geospatial information system.
• attributes such as the degree of match between search terms and entity description text and historical search preferences of an individual user or users in aggregate, that may be incorporated into an interactive GIS as described herein as elements used to determine an entity score.
• the ranking may be used for purposes other than selection for display.
• FIGS. 3 and 4 are flow charts illustrating steps performed to generate and serve ranked entity data in accordance with embodiments of the invention. Not every possible step is shown in the figures. In addition, some embodiments perform different steps in addition to, or instead of, the ones described herein. Furthermore, the order of the steps can vary from that described herein.
• FIG. 3 illustrates a method for generating and providing prioritized entities in accordance with an embodiment of the invention.
• One or more steps may be performed by an entity ranking module such as the one depicted in FIG. 2 and implemented on the client and/or server side as shown in FIG. 1 .
• certain steps for instance 350
• others may be performed ‘off-line’ outside the context of a particular search request.
• entity data is received 310 from various sources such as the data sources discussed with reference to FIG. 1 .
• Ranking data is also received 320 , from the same or different sources as the entity data.
• the collection of data may take place, for instance, as part of a database construction process, or a web crawl and indexing process. Such data may also be pushed from vendors or third party sources. Some portions of the data, for instance, data about a user's personal placemarks, may be updated in real-time in response to a user request while others are received or refreshed according to a regular schedule.
• Various mechanisms such as those described above may be applied to the ranking data to determine 330 rankings or scores for the entities.
• Comparable attribute scores based on disparate types of ranking data obtained from various sources can be calculated using the techniques described above.
• the entity data may be stored in a database such as the one shown in FIG. 1 , or in another embodiment, a subset of the ranked entity data is cached in a memory of a client hosting an entity ranking module that determines 330 entity rankings based on the cached data.
• ranked entity data is used to generate 340 layers of placemarks for display on maps.
• the entities are mapped to placemarks, and stylings are applied based on the category in which an entity or placemark falls.
• Groups of placemarks are correlated to levels of detail in order to present a viewer of a map with an appropriate density of placemarks.
• the levels of detail may reflect any number of inputs, including the altitude at which a map is being viewed, the resolution of the map, other layers depicted on a given map, and user preferences about how sparse or dense a map should be.
• placemarks may also be organized into categories such that an individual placemark can be associated with different groups of placemarks, e.g. placemarks associated with a specific city as well as placemarks of tourist destinations. Each of these categories may be reflected a separate placemark layer.
• a request for a placemark layer or layers is received 345 , and the appropriate layers are provided 350 to the requester.
• a digital map may be generated according to raster, tiled, or vector-based methods.
• a placemark layer may be requested by a map server in real-time in response to a query, or provided 350 to create map components that are pre-stored and only served when a user request is received.
• the placemark layers are provided 350 in response to user preferences or selections.
• the placemark layer is combined with other layers to form a map, at a client or server site.
• FIG. 4 is a flow chart illustrating steps for requesting and receiving a map including prioritized placemarks in accordance with an embodiment of the invention.
• FIG. 5 illustrates a map that could be received based on a request formulated using steps in the processes depicted in FIG. 4 .
• One or more of these steps may be performed at a client requesting a map from a map server as shown in FIG. 1 .
• the process begins when a map is requested 410 by a client, for instance from within a browser, specialized application such as Google Earth, or other software application.
• the map request identifies the geographic area for which the map is sought and the altitude the map should represent.
• User or client data and preferences are also provided 420 to a map server system.
• the country from which the request originates which can be determined based on the IP address of the request, for instance, and a user's language preferences are provided to a map server so that only placemarks in the appropriate language and which reflect country or culture-specific stylings or sources of data are served.
• the country and language information may be provided 420 from the requesting application or another source such as the operating system of the client.
• user placemark preferences may also be provided 420 to the map system.
• the preferences may reflect for instance, which categories or layers of placemarks to display, how many placemark to include (density), and how much identifying information should be displayed on a map. For instance, in the case of the map of FIG. 5 , a user can select, using checkboxes on a graphical user interface 520 , which layers should be included on the map displayed 550 .
• Each layer of placemarks is associated with its own icon or styling, for instance, a knife and fork icon 510 A for a dining placemark, and a cup 510 B for a drinking establishment.
• preferences provided 420 to the map system can be used to personalize the selection and display of placemarks to the user.
• Personalized placemark selection may be accomplished in a variety of ways, for instance by personalizing entity ranking by using a user's behavior or usage patterns as the basis of an attribute upon which an entity's rank is scored or varying the weight given to certain attributes based on a user's input; or, for example, by overriding generalized ranking schemes by always including placemarks that the user has defined or designated herself.
• a requester may receive 432 various types of data depending on the personalization preferences provided to the map server system.
• there are no personalized placemarks 430 A and the client receives 432 A and displays 450 A a map with general placemarks.
• no entity ranking capabilities are implemented locally at the client.
• a client requests that the requested map include only personalized placemarks 430 C.
• entity ranking capabilities are implemented wholly at the client, with an entity ranking module such as the module described in FIG. 2 hosted locally rather than on a centralized server.
• the client receives 432 A a map, comprised of map layers, which does not include any placemarks on it. Personalized placemarks generated and stored at the client are added 440 A to the map, and the resulting map is generated and displayed for the user.
• the user may request a map that includes both personal and general placemarks 430 .
• the client receives 432 B a map and a group of general placemarks or entities associated with the geography of the map based on this request.
• the general placemarks are combined with personal placemarks that have been designated by the user in any of a variety of ways (for instance by authoring the entity definition or placing the placemark in a favorites folder), and a ranking mechanism is applied 436 B to the combined group of placemarks.
• the results are used to generate 440 B a layer that includes both personal and generalized placemarks, which is then combined with the map provided to the client to generate 450 B a map for display 450 B.
• FIG. 5 shows an exemplary map including personal and general placemarks that has been generated in accordance with the method described at steps 412 - 420 and 430 B through 450 B.
• personal placemarks including Max's playground 105 and Dirk's coffee spot 419 are depicted together with dining (e.g. 510 A) and drinking placemarks (e.g. 510 B) on the map 550 .
• community placemarks which are demarcated with a special community placemark icon 540 .
• the map 550 also includes interactive content, in the form of a text box 530 that links to a comment about a placemark provided by a community member. This allows a user to benefit from the input provided by other community members.

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