WO2012082163A1 - N-dimensional affinity confluencer - Google Patents

Abstract

An N-dimensional affinity confluencer comprises an affinity table to maintain a plurality of affinities for each of a plurality of wireless devices. A sphere of influence (SPIN) table provides an influence for determination of a confluence between affinities maintained in the affinity table. An affinity confluence determination module determines an affinity confluence between the plurality of wireless devices and an influence parameter associated with the sphere of influence (SPIN) table. An affinity confluence is determined from among a plurality of wireless devices by determining a confluence of at least two predefined affinities from among a plurality of wireless devices. A sphere of influence parameter is applied to the confluence to determine those of the plurality of wireless devices defined by an affinity confluence. The plurality of wireless devices need not be within a common electrical network.

Description

N-DIMENSIONAL AFFINITY CONFLUENCER

BACKGROUND OF THE INVENTION

1. Field of the Invention

This invention relates generally to telecommunications. More particularly, it relates to wireless based technologies.

2. Background of the Related Art

People perceive the universe as existence within the three (3) dimensions of space and the fourth (4^th) dimension of time and they generally think of themselves as "passing through" these dimensions. In other words, people generally think of space as fixed or static and think of themselves as traveling through space from one point to another. People generally think of themselves as traveling forward through time where any particular moment is simply "now" and that "now" then immediately becomes part of "the past".

SUMMARY OF THE INVENTION

In accordance with the principles of the present invention, an N- dimensional affinity confluencer comprises an affinity table to maintain a plurality of affinities for each of a plurality of wireless devices. A sphere of influence (SPIN) table provides an influence for determination of a confluence between affinities maintained in the affinity table. An affinity confluence determination module determines an affinity confluence between the plurality of wireless devices and an influence parameter associated with the sphere of influence (SPIN) table.

In accordance with a method of determining an affinity confluence from among a plurality of wireless devices in accordance with another embodiment of the invention comprises determining a confluence of at least two predefined affinities from among a plurality of wireless devices. A sphere of influence parameter is applied to the confluence to determine those of the plurality of wireless devices defined by an affinity confluence. The plurality of wireless devices need not be within a common electrical network.

BRIEF DESCRIPTION OF THE DRAWINGS

Features and advantages of the present invention become apparent to those skilled in the art from the following description with reference to the drawings:

Fig. 1 depicts the function of an exemplary N-dimensional affinity confluencer, in accordance with the principles of the present invention.

Fig. 2 depicts five (5) exemplary data structures established within the N-dimensional affinity confluencer (in this example a 5-dimensional affinity confluencer), to manage affinities, SPINs, and the identification of relationships therebetween.

Fig. 3 elaborates the juxtaposition of attractive and repulsive inducement versus receptive and projective influence, and defines several permutations of influence between wireless devices, as represented by their sphere of influence, in accordance with the principles of the present invention.

Fig. 4 depicts a wireless device user's location, in accordance with the principles of the present invention.

Fig. 5 shows an exemplary location (LOC) table, in accordance with the principles of the present invention.

Fig. 6 shows an exemplary primary matrix, in accordance with the principles of the present invention. DETAILED DESCRIPTION OF ILLUSTRATIVE EMBODIMENTS

Fig. 1 depicts the function of an exemplary N-dimensional affinity confluencer, in accordance with the principles of the present invention.

In particular, as depicted in Fig. 1 , the present invention inverts the relationship of a wireless device within space-time and instead depicts a human being's wireless device as a "personal sphere of influence" 105 (Hereafter referred to as a SPhere of INfluence or "SPIN") transected by a virtually infinite number of "planes of interaction". This allows the perception of potential interactions between not just the physically concrete elements of day to day life but also the many digital (i.e. virtual) elements of modern life which have little if any physically concrete representation.

A simple embodiment of an N-dimensional affinity confluencer 100 in accordance with the principles of the present invention implements several dimensions of affinity, e.g., a plurality .of wireless device users' respective locations 110, a plurality of user's interest in health and fitness 114, and retailers' offerings 112. The combination of these three (3) exemplary "planes of interaction" define a specific affinity confluence 101 for a given wireless device where the location of the user of that wireless device, and their interest in health and fitness, creates an opportunity for influence.

The opportunity for influence may be a projection of influence. For example, a broadcast of a wireless device user's interest in health & fitness, in combination with the user's location, may elicit an action on the part of a member of a third dimension of affinity, in this case a retailer.

Alternatively, or additionally, the opportunity for influence may be a reception of influence; if, for example, the person had joined a health & fitness social group (opt-in) affiliated with a particular natural foods and supplements retailer, then the intersection with a fourth dimension - location - of the plurality of users provide a proximity of a wireless device user to a given retailer's outlet store (i.e., a confluence of an intersection of affinity planes of a given user with the retail affinity plane 112) might elicit some form of message from the retailer to the user of the wireless device at the affinity confluence 101 identified by the affinity confluencer 100. The proximity is preferably configurable and defined by a region in the location plane.

Note that in this description of the invention use of the word "network" is purposely avoided as the word "network" has been so overloaded and over-used that resulting undesired connotations are inevitable. Each affinity plane does not necessarily define a group of wireless devices that necessarily are in communication with one another. Rather, the affinity planes are defined by configurable parameters of wireless devices, mostly configured by the respective users, and thus each affinity plane of interaction/interest may be and likely are constantly changing.

For illustrative purposes, the present invention represents each affinity plane as flat and skewed in any of a number of different directions, but the fact of the matter is that affinity planes of interaction/interest are constantly in a state of flux, constantly rippling and vibrating with changes caused by other wireless device users and/or other spheres of influence. It's the very dynamism of plane of interaction and the transitory nature of affinity confluences, and the determination of the same by the N-dimensional affinity confluencer 100, that are a principal focus of the present invention. The N-dimensional affinity confluencer 100 automatically resolves and acts upon these highly transitory affinity confluences.

The N-dimensional affinity confluencer 100 may be implemented in an appropriate server and established at an appropriate location on a carrier or provider's wireless network.

Fig. 2 depicts five (5) exemplary data structures established within the N-dimensional affinity confluencer 100 (in this example a 5-dimensional affinity confluencer), to manage affinities, SPINs, and the identification of relationships therebetween.

In particular, as shown in Fig. 2, one (1) active plane of affinity is uniquely identified by two (2) keywords and two (2) active SPINs.

In the given example, all affinities are maintained using two (2) specific data structures: an Affinity Table 110, and a Keyword-List Table 114.

All participating SPINs are maintained using one (1) primary data structure: a SPIN Table 112.

The relationship between affinities and SPINs is managed using, e.g., two (2) additional data structures: a SPIN-List Table 116, and an Affinity-List Table 118.

Each record or row in the Affinity Table 110 includes (but is not limited to) an "Affinity ID" as the primary key, a "Keyword-List Link", and a "SPIN- List Link". In the given example every defined Affinity must have at least one Keyword-List entry (i.e. at least one keyword) with which to uniquely identify the Affinity; Keyword-List Link fields are preferably not allowed to be set to a TERMINATOR value. Affinities that are defined but have zero (0) associated SPINs must set the Affinity's SPIN-List Link to a TERMINATOR value 111.

Note that in this description the word "Link" is used to denote any reference/dereference mechanism used to access information from a data structure other than the data structure in which the Link resides.

Each record or row in the Keyword-List Table 114 includes (but is not limited to) a "Keyword-List ID" used as the primary key, a "Keyword", an "Affinity Link", and two (2) Keyword-List Link values called "Precede" and "Succeed" which are used to create a doubly-linked list of the keywords used to uniquely identify the Affinity. The Keyword field of a Keyword-List entry may be set to any representation of a keyword except the null or empty set. The Affinity Link field of a Keyword-List entry must refer back to one and only one associated Affinity Table entry; the Affinity Link fields are not allowed to be set to a TERMINATOR value. The PRECEDE and SUC.GE|¾|¾ds of a Keyword-List entry are also not allowed to be set to a TERMINATOR value. The PRECEDE and SUCCEED fields must always refer to an entry in the Keyword-List Table. Keyword-Lists that^' are comprised of one and only one (1) keyword will set the values of both PRECEDE and SUCEED to refer to that one Keyword-List entry; PRECEDE and SUCCEED will refer to or point to each other 115.

Every participating SPhere of INfluence (SPIN) is represented by one (1) and only one entry in the SPIN Table 112. Each record or row in the SPIN Table 112 includes (but is not limited to) a SPIN ID used as the primary key, miscellaneous SPIN information that may be a multitude of sub-fields some of which may actually refer to other data structures or other data sources entirely, and an Affinity-List Link. Participating SPINs for which zero (0) affinities have been identified must set the SPIN'S Affinity-List Link to a TERMINATOR value 113. Relationship or association between Affinities and SPINs is managed with the SPIN-List Table 116 and the Affinity-List Table 118. The SPIN-List Table is 116 intended to allow someone to start with one (1) entry in the Affinity Table and find all SPINs associated with that Affinity. The Affinity-List Table is intended to allow someone to start with one (1) entry in the SPIN table and find all Affinities with which the SPIN is associated.

Each record or row in the SPIN-List Table 116 includes (but is not limited to) a SPIN-List ID used as the primary key, an Affinity Link, a SPIN Link, and two (2) SPIN-List link values used to create a doubly-linked list of the SPINs associated with the Affinity. The Affinity Link and SPIN Link fields are not allowed to be set to a TERMINATOR value; entries in the SPIN-List Table are only created when a relationship between an Affinity and a SPIN is created so there will always be both a reference to an Affinity as well as a reference to a SPIN. PRECEDE and SUCCEED fields must always refer to an entry in the SPIN-List Table. SPIN-Lists that are comprised of one and only one (1) SPIN set the values of both PRECEDE and SUCEED to refer to that one SPIN-List entry; PRECEDE and SUCCEED refer to or point to each other 117.

Each record or row in the Affinity-List Table 118 includes (but is not limited to) an Affinity-List ID used as the primary key, an Affinity Link, a SPIN Link, and two (2) Affinity-List link values used to create a doubly-linked list of the Affinities with which the SPIN is associated. The Affinity Link and SPIN Link fields are not allowed to be set to a TERMINATOR value; entries in the Affinity- List Table are only created when a relationship between an Affinity and a SPIN is created so there is always both a reference to an Affinity as well as a reference to a SPIN. PRECEDE and SUCCEED fields must always refer to an entry in the Affinity-List Table. Affinity-Lists that are comprised of one and only one (1) Affinity set the values of both PRECEDE and SUCEED to refer to that one Affinity-List entry; PRECEDE and SUCCEED refer to or point to each other 119.

Persons adept in the art of data management will readily understand that there are many, many interesting ways of accessing and using information contained in the five (5) structures defined above. The tenets of this invention are not intended to encompass only the uses described above but rather any mechanism, methodology, or use which enterprising persons find for the data contained therein.

As another embodiment of this invention, location forms the lynchpin for defining N-Dimensional Affinity Confluences. In this case the principal plane of interaction transecting the sphere of influence is location. Use of location as the primary vector of every Affinity Confluence juxtaposes the exertion of influence (i.e. projection and reception) versus "Attraction" and "Repulsion" inducements to fully parameterize the bounds of the invention.

For the purposes of this invention, influence will be defined from the standpoint of a wireless device user's SPhere of INfluence (SPIN). Projection of influence specifically means that the wireless device's location and other predefined affinities configured by its user cause an unplanned action by someone or something else such that the action is directed at the wireless device. The wireless device's location + affinities + projected influence cause an instantaneous and unplanned action. The projection of influence can also be represented as "unprofiled" or "analytic" in the sense that it was not the result of settings or parameters of a personal profile defined by the person prior to the time of the action but rather the result of analysis of a gamut of various data that results in the instantaneous realization of influence. Reception of influence specifically means that the wireless device's location and pre-defined affinities cause an action planned by someone or something else such that the action is directed at the wireless device (i.e., subscription or opt-in). Not that the planned action is not simply scheduled to take place on a particular day at an appointed hour - rather in accordance with the principles of the present invention if a wireless device configured or otherwise associated with given affinities also satisfies specific location parameters, then that wireless device receives action/influence from another wireless device, network server, third party, or other device in communication with that wireless device. The reception of influence can be represented as "profiled" or "deterministic" in the sense that it was the result of settings or parameters of a personal profile defined by the person prior to the time of the action. There is, of course, some analysis involved in the determination of either projective or receptive influence but the fundamental difference is the existence (or non-existence) of predefined parameters.

For the purposes of this invention, Attractive Inducement and

Repulsive Inducement are defined from the standpoint of elements within the planes of affinity. Elements of Interaction that prefer to garner or concentrate a wireless device user's attention upon the element exert Attractive Inducement. Elements of Interaction that prefer to dissuade a wireless device user from concentrating on the element exert Repulsive Inducement.

Fig. 3 elaborates the juxtaposition of attractive and repulsive inducement versus receptive and projective influence, and defines several permutations of influence between wireless devices, as represented by their sphere of influence, in accordance with the principles of the present invention.

In particular, as shown in Fig. 3, the invention uses communication in various forms to represent the exertion of influence and inducement regardless of whether projected or received versus attractive or repulsive. This invention contemplates the use of any appropriate mode of communication to the wireless device user, in all its many forms, if that communication involves these human senses:

Audible - depending on the sense of hearing.

Visible - depending on sight.

Tactile - depending on the sense of touch.

Olfactory - depending on the sense of smell.

This invention uses communication to represent the exertion of influence/inducement but does not limit the concept to just communication. For instance, the projection of repulsive inducement from a secure US Military complex toward a wireless device user perceived to be an intruder may, conceivably, be physical.

Yet another embodiment of the invention uses proximity as the foundation for actualizing location based N-Dimensional Affinity Confluences. For the purposes of this embodiment the proximity evaluation is designed for speed of performance during proximity evaluation processing.

Fig. 4 depicts a wireless device user's location, in accordance with the principles of the present invention.

In particular, as shown in Fig. 4, the invention reduces a wireless device's location, represented, e.g., in decimal degrees of latitude and longitude, into indices of latitude and indices of longitude within four (4) layers: 1) Primary

120: tens of degrees (~700 statute mile resolution); 2) Secondary 121: degrees

(-70 statute mile resolution); 3) Tertiary 122: minutes (-6000 foot resolution); and 4) Quaternary 123: seconds (-100 foot resolution). This figuratively covers the Earth's surface with successively finer grained gridlines. Seconds of latitude and longitude yield a grid whose vertices are approximately 100 feet apart at the equator and somewhat closer together the farther away from the equator (North or South) the person is located.

Should the need arise to attain even finer granularity than seconds, a fifth (Quinary) and even sixth (Senary) layer may be added to represent 10ths of seconds (-10 feet) and 100ths of seconds (-12 inches).

Every time a person's location is registered the Proximity Nexus will save that person's identifier, location (latitude and longitude), and optimization indices in a LOC table.

Fig. 5 shows an exemplary location (LOC) table, in accordance with the principles of the present invention.

In particular, as shown in Fig. 5, the Lat and Lon values are normalized to be decimal degrees in the range -90.0 through +90.0 for Latitude and -180.0 through +180.0 for Longitude. The indices are computed thusly:

PrimaryX = int( round(( Lon / 10.0 ) - 0.5))

PrimaryY = int( round(( Lat / 10.0 ) - 0.5))

PrimaryZ = Altitude modulo 700 statute miles

Secondary X = int( truncate( Lon - (PrimaryX * 10.0)))

SecondaryY = int( truncate( Lat - (PrimaryY * 10.0)))

SecondaryZ = Altitude modulo 70 statute miles TertiaryX = int( truncate((Lon - ((PrimaryX * 10.0) + SecondaryX )) * 60.0)) TertiaryY = int( truncate((Lat - ((PrimaryY * 10.0) + SecondaryY )) * 60.0)) TertiaryZ = Altitude modulo 6000 feet

Quaternary X = int( truncate((Lon - ((PrimaryX * 10.0) + SecondaryX + (TertiaryX / 60.0))) * 3600.0))

QuaternaryY = int( truncate((Lat - ((PrimaryY * 10.0) + SecondaryY + (TertiaryY / 60.0))) * 3600.0))

QuaternaryZ= Altitude modulo 100 feet

Note that these equations presume that the round() function always rounds an "n.5" value up so that 0.5 becomes 1.0, 2.5 becomes 3.0, -3.5 becomes -3.0, etc. Some adjustments may be necessary to accommodate specific hardware architectures, operating systems, and compilers, as will be appreciated by those of skill in the art.

The intent, though, is to compute an index based on the lower left corner of the square in which the wireless device is located. The Primary square (See 'Q' in Fig.4) is a 10 degree by 10 degree square. The Secondary square (See 'R' in Fig.4) is a one degree by one degree square located within the Primary. The Tertiary square (See 'S' in Fig.4) is a one minute by one minute square located within the Secondary. The Quaternary square (See T in Fig.4) is a one second by one second square located within the Tertiary.

These computations produce values in the following ranges:

-18 <= PrimaryX <= 18 -9 <= PrimaryY <= 9 -1 <= PrimaryZ <= 36

0 <= SecondaryX <= 9 0 <= SecondaryY <= 9 -1 <= SecondaryZ <= 357 0 <= TertiaryX <= 60 0 <= TertiaryY <= 60 -1 <= TertiaryZ <= 22,000 0 <= QuaternaryX <= 60 0 <= QuaternaryY <= 60 -3 <= QuaternaryZ <= 1.32e06

Fig. 6 shows an exemplary primary matrix, in accordance with the principles of the present invention.

In particular, as shown in the primary matrix of Fig. 6, the Proximity Nexus maintains a collection of matrices. This collection of matrices always includes a matrix for the Primary indices (i.e. a "Primary Matrix"). The primary matrix is accompanied by a PrimaryCount indicating how many wireless devices or SPIN are present.

The Primary Matrix is also accompanied by an array or list of the primary matrix elements in which wireless devices/SPIN can be found. (The list is empty if PrimaryCount is zero.)

Each element in the 36x18 Primary matrix contains: (1) a count of how many wireless devices/SPIN are present in that particular 10deg X 10deg area; and (2) a reference to a Secondary Matrix. (The reference is NULL if count is zero).

Secondary (10x10 matrix), Tertiary (60x60), and Quaternary

(60x60) matrices are allocated, maintained, and eliminated as needed to manage Proximity Nexus memory use.

Each Secondary Matrix is accompanied by a SecondaryCount indicating how many wireless devices/SPIN are present in that 10deg X 10deg area.

Each Secondary Matrix is also accompanied by an array or list of

is zero.)

Each Tertiary Matrix is accompanied by a TertiaryCount indicating how many wireless devices/SPIN are present in that 1deg X 1deg area.

Each Tertiary Matrix is also accompanied by an array or list of the tertiary matrix elements in which wireless devices/SPIN can be found. (The list is empty if its TertiaryCount is zero.)

Each element in a 60x60 Tertiary matrix contains: (1) a count of how many wireless devices/SPIN are present in that particular 1 minute X 1 minute area; and (2) a reference to a Quaternary Matrix. (The reference is NULL if count is zero.) Each Quaternary Matrix is accompanied by a QuaternaryCount indicating how many wireless devices/SPIN are present in that 1min X 1min area.

Each Quaternary Matrix is also accompanied by an array or list of the quaternary elements in which wireless devices/SPIN can be found. (The list is empty if QuaternaryCount is zero.)

Each element in a 60x60 Quaternary matrix contains: (1) a count of how many wireless devices/SPIN are present in that particular 1 second X Isecond area; and (2) an array or list of wireless device/SPIN Identifiers that are present in the 1sec X 1sec area. (The list is empty if count is zero.)

The evaluation of '∑' axis differences are preferably not managed in a matrix structure but rather are evaluated in near real-time as a simple difference of like Z values (i.e. primary, secondary, tertiary, etc.). If the absolute value of the computed Z-difference (i.e. delta Z) is within the defined vertical bounds of proximity, then proximity has been successfully established. The same kind of approaching or retreating event (described in more detail later in this disclosure) results if the delta Z grew or shrank because a wireless device user was, e.g., riding an elevator, or climbing stairs within a building, even if the lateral X and Y components stayed well within the bounds of a predefined or configured proximity.

Maintenance of this four (4) tier structure is complex but considered obvious to those skilled in data structures and is not described further in this disclosure.

This four (4) tier data structure makes it possible for the Proximity Nexus to rapidly identify all of the wireless devices/SPIN in a predefined or preconfigured close proximity to an Affinity Confluence so that Influence and Inducement are resolved in a timely manner.

Proximity may be a configured reference value, e.g., defined in terms of hundreds of feet, thousands of feet, tens of miles, or hundreds of miles. The Proximity Nexus is able to rapidly identify which wireless devices/SPIN meet the criteria. The broader the defined proximity value, the longer it takes the Proximity Nexus to send all the notifications due to latencies imposed by the communication media.

The "Time Tag" element of each row in the LOC table (e.g., as shown in Fig. 5) is specifically intended to allow the quantification and actualization of time as one of the many affinity planes (or planes of interaction) that transect all SPheres of INfluence (SPINs). The confluence of time and location plus many other potential affinity planes of interaction give each wireless device the ability to quantify when it authorizes to either project or receive influence, or when it authorizes to be subject either to attractive or repulsive inducement. In this way particular affinity confluences may be scheduled in the N-dimensional affinity confluencer 100 for particular hours during the day or particular days of the week.

Similarly, an affinity confluence of location and business interests or a confluence of location and interests in art (or politics or music or whatever) that is typically not temporally constrained could be scheduled NOT to exert influence or react to inducement during a specific timeframe (e.g. for instance during a vacation of a particular wireless device user).

Proximity lends itself quite well to providing life enhancing service to wireless device users without unduly compromising privacy of information thereon because proximity notifications reveal neither the location of the wireless device receiving the notification, nor the person operating the wireless device to whom the notification refers. The Proximity Nexus certainly maintains as precise a location for every participating wireless device/SPIN as it is able to acquire, but the Proximity Nexus is intended to run inside a secure environment and reveal as little about the actual location(s) of the participants as is practical for any particular application or service. This simple fact makes proximity an excellent mechanism with which to actualize location based N-Dimensional Affinity Confluences in the N-dimensional affinity confluencer 100.

Primary facets of that actualization are proximity events. There are, e.g., two (2) principal proximity events about which some type of notification would be sent: (1) An Approaching event (i.e., a distance between evaluees is reducing); or (2) A Retreating event (i.e., a distance between evaluees is increasing).

Proximity events can be parameterized to even multiples of the base unit of measure for each of the four (4) to six (6) levels of accuracy/fidelity that the Proximity Nexus uses to track location data. If, for example, the Proximity Nexus provides four (4) levels of fidelity, then proximity events may be keyed to, e.g., even multiples of ~700 statute miles, even multiples of ~70 statute miles, even multiples of ~6000 feet, and even multiples of ~100 feet. Some of these overlapping fidelities clearly match, in the detail.

In yet another embodiment of the invention, the Proximity Nexus uses the lowest level of fidelity (i.e., the most coarse granularity) of matrix with which to satisfy any proximity event detection. So, for example, if a proximity event were parameterized as 12,000 feet, then the Proximity Nexus uses an even multiple of '2' against the Tertiary Matrix rather than an even multiple of 120 against the Quaternary Matrix. This is performed as an optimization for proximity event evaluations.

An alternate form of such an evaluation parameterizes the numeric value at which the fidelity of proximity events gets "rounded up" to provide nearly the same level of fidelity as was requested by the wireless device while providing the maximum performance possible (i.e. minimum evaluation time duration).

The Proximity Nexus includes configurable and parameterized hysteresis so that if the wireless device stimulating the proximity event, e.g., takes a track that skirts the edge of the proximity boundary, then the wireless device to which the event notification(s) is sent doesn't get barraged with the digital equivalent of "proximity SPAM". As such a wireless device stimulating a proximity event needs to approach (or retreat) a certain distance past the notification threshold before it would be possible to generate the opposite form of proximity notification.

In accordance with another embodiment of the present invention, the method or mechanism constantly re-computes, within the bounds of any particular element within the proximity matrix, an indication of that node's current "Affinity-Vector". The Affinity-Vector is simply a reference from each proximity matrix element to the single Affinity entry (See Fig.2) that is represented within that proximity matrix element in the greatest numbers. If, for example, there were 40 wireless devices in a particular Quaternary node (i.e. ~100ft resolution) and 25 of them are associated with an "Alaska Sport Fishing" affinity plane, where no other affinity to which those 40 wireless devices are associated totaled more than 7 or 8 wireless devices, then the Affinity-Vector for that quaternary node is a link to the "Alaska Sport Fishing" affinity plane. A key point, with regard to a node's affinity-vector, is that the affinity-vector is computed specifically for the purposes of manifesting attractive or repulsive inducement.

Other embodiments within the principles of the present invention are possible, including but not limited to the following types or examples of N- Dimensional Affinity Confluencers:

1) My Location + "people against speeding tickets" + cellular announcement of radar/laser detection ahead (see, e.g., Cellular Augmented

Radar/Laser Detector U.S. Patent 7,471 ,236).

2) Location of my vehicle + vehicle theft deterrence + activation of vehicle's alarm (see, e.g., Cellular Augmented Vehicle Alarm patent U.S. Patent 7,825,780).

3) My Location + interest in locally broadcast, pseudo-anonymous, text communication (CB-SMS).

4) Location + advertised interest in social interaction + 'N' element list of hobbies & interests (SMS-Roulette).

5) My Location + interest in Quisine|Theater|Sporting-Event|Retail- Offering|Childrens-Event|Street-Fair|Street-Performer + desire to participate.

6) My Location + interest in Quisine|Theater|Sporting-Event|Retail- Offering|Childrens-Event|Street-Fair|Street-Performer + desire to avoid.

7) My Location + cruise ship arrival schedule + desire to successfully secure parking.

8) My Location + Crime/Accident/Fire/HAZMAT incident + desire to avoid. 9) My Location + planned roadwork + desire to avoid.

10) My location + unplanned roadwork + desire to avoid.

11) Child's Location|Elder Parent's Location|Dependant's Location + miscellaneous event + desire to help them participate.

12) Child's Location|Elder Parent's Location|Dependant's Location

+ miscellaneous event + desire for them to avoid.

13) Location of preferred Band|Taco-Bus|Rave-Event|Team|Car- Club(s) + desire to participate.

14) My Location + anti-affinity + others' location + others' affinity + desire to avoid.

15) Strong affinities over an area + area advertisement.

16) Strong anti-affinities over an area + elimination of strongly unwanted area advertisements.

7) Lack of affinities over an area + area advertisement + desire to discover new things.

18) Political affinities over a region + candidates' desire to focus campaign spending.

19) My Location (or future location) + weather in an area + desire to be alerted.

20) My vehicles location + vehicle onboard computer measuring gas levels + gas stations location (ranked by price) + alert when gas level is low.

21) My vehicles location + vehicle onboard computer estimating miles left before out of gas + gas station location + alert you better get gas now.

22) My vehicles location + highway rest areas + time of continuous driving + alert rest area ahead (and how far) or better stop at this rest area.

23) My vehicles location + vehicle onboard computer measuring mileage since oil change + oil changing stations + alert when time to change oil.

While the invention has been described with reference to the exemplary embodiments thereof, those skilled in the art will be able to make various modifications to the described embodiments of the invention without departing from the true spirit and scope of the invention.

Claims

CLAIMS What is claimed is:

1. An N-dimensional affinity confluence!-, comprising: an affinity table to maintain a plurality of affinities for each of a plurality of wireless devices;

a sphere of influence (SPIN) table to provide an influence for determination of a confluence between affinities maintained in said affinity table; and

an affinity confluence determination module to determine an affinity confluence between said plurality of wireless devices and an influence parameter associated with said sphere of influence (SPIN) table.

2. A method of determining an affinity confluence from among a plurality of wireless devices, comprising:

determining a confluence of at least two predefined affinities from among a plurality of wireless devices;

applying a sphere of influence parameter to said confluence to determine those of said plurality of wireless devices defined by an affinity confluence;

wherein said plurality of wireless devices heed not be within a common electrical network.

3. The method of determining an affinity confluence from among a plurality of wireless devices according to claim 2, wherein:

said sphere of influence parameter is location.