KR20070022140A - Method and system for enhanced capacity and quality over WLAN - Google Patents

Abstract

Disclosed herein are methods and systems for controlling wireless communication between a mobile terminal 5 and a plurality of wireless access points 92. Link state and quality data are determined for each communication link between the mobile terminal 5 and each wireless access point 92 currently detectable by the mobile terminal. A priority list of detected wireless access points is also generated. In addition, access point status and quality data are determined for the wireless access points themselves and / or a network connecting the wireless access points. Such access point data may not be accessible to the mobile terminal. The access point data may also include the status and / or quality of neighboring wireless access points that are near the detected wireless access points but have not yet been detected by the mobile terminal. The link data, access point data and the other ranks are used to select the best access point to communicate with the mobile terminal 5.

Description

Method and system for enhanced performance and quality over wireless local area network [Method and system for enhanced capacity and quality over WLAN}

The present invention relates to communication control between a mobile terminal and one or more wireless access points, and more specifically to the current state of the communication links for the wireless access points available and the network of available access points. It is about making it possible to select one wireless access point based on that.

In recent years, the prevalence and dissemination of wireless local area network (WLAN) deployments has dramatically increased. Contributing to this increase is the Institute of Electrical and Electronics Engineers (IEEE) 802.11, which defines physical operating parameters, packet formats, and protocol behaviors for data exchange between mobile terminals and wireless access points. Communication standards such as standard suites. These standards also typically define interactions between mobile terminals and access points to coordinate handoff from one wireless access point to another. However, the standards do not necessarily indicate how handoff decisions are made. Typically, mobile stations evaluate the locally measured radio signal strength of beacons transmitted by adjacent access points to select an access point through the strongest signal and the highest available data rate. For most practical purposes, this metric results in selecting the physically closest access point. However, due to the variety of networks, the closest access point is not always the best access point.

For example, providing high quality and reliable voice communication through access points of WLAN services has been a difficult problem. Voice applications typically transmit small data packets (eg 40-60 bytes) but transmit data packets very frequently (eg, every 20 milliseconds). Thus, voice applications are sensitive to network latency, reliability, and performance. Packets of voice data that do not reach "on time" as quickly or as compared to other voice data have little or no value to the listener. Delays, losses, and re-ordering of packets are typically manifested in "clicks", "pops", and miscellaneous poor sound quality for the listener. In addition, because voice data packets are small, a relatively high rate of overhead data and processing is required to identify and route voice data packets. In addition, since WLAN standards typically support multiple data rates, the performance of the overall access points usually depends very much on the number and location of mobile terminals, as well as the type of traffic being transmitted. Moreover, since WLAN connections are typically using an unlicensed radio freqency (RF) spectrum, transmitters can legitimately claim a shared channel. Competition for broadcast time can increase latency due to collision detection, retransmissions, and reduced data rates (and consequently increased propagation time and RF resource usage). All of these network performance factors contribute to the quality of voice calls or other communications using WLANs. However, mobile terminals typically select an access point based on wireless signal strength and locally available information such as biasing the mobile terminals to select the "closest" access point. The point may not be an access point that will provide the best quality voice call or other communication.

1 is a schematic diagram illustrating components that may be included in a mobile terminal.

2 is a functional block diagram of an enterprise configuration of functional elements for a representative embodiment of the present invention.

3 is a flow diagram illustrating exemplary logic for controlling communication between a mobile terminal and one or more wireless access points.

4 is a flow diagram illustrating exemplary logic for a call quality manager (CQM) for evaluating wireless access points associated with mobile terminals.

Various embodiments of the invention will be described in detail with reference to the drawings, wherein like reference numerals refer to like parts, assemblies, and / or operations. The scope of the invention is not limited by reference to the various embodiments, which are limited only by the scope of the claims appended hereto. In addition, any of the examples described herein are not intended to limit the various possible embodiments of the claimed invention, but are merely intended to show some of the several possible embodiments of the claimed invention.

Throughout the specification and claims, the following terms have the meanings explicitly associated in the specification and claims, unless the context clearly indicates otherwise. The meanings mentioned below are not intended to limit the terms, but merely provide illustrative examples of the terms. The meaning of "any", "one", "above" includes a plurality of references, and the meaning of "in" includes "in" and "on". The expressions “in one embodiment” and “representative embodiment” as used herein may refer to the same embodiment, but need not necessarily refer to the same embodiment. The term " connected " means a direct electrical connection between items to be connected without any intermediate device. The term "connected" means either a direct electrical connection between the items to be connected, or an indirect connection through one or more passive or active intermediate devices or media. The terms “communicate” and “communicating” mean that the elements may be connected, connected, and / or functionally exchange information in a wireless manner via a medium such as air. The term "interface" means an active or passive combination of a single component, a plurality of components, a single software module, a plurality of software modules, and / or the former, which are in communication to provide the desired operation. The term "signal" means at least one current, voltage, charge, temperature, data, or other detectable element. The term "operation" means one or more actions, steps, procedures, and / or functions.

A representative embodiment of a mobile terminal communicating with one or more wireless access points included in a network of wireless access points communicating with a network monitoring apparatus will be described. 1 shows an exemplary mobile terminal 5 according to one embodiment of the invention. In one embodiment, the mobile terminal 5 is a cellular telephone configured to transmit and receive voice communications and messages, such as Short Messaging Service (SMS) messages, via one or more wireless communication interfaces. In general, the mobile terminal 5 may comprise any device capable of communicating with one or more wireless networks via one or more wireless access points. Such devices include cellular telephones, smart phones, pagers, radio frequency (RF) devices, infrared (IR) devices, integrated devices combining one or more of the previous devices, and the like. There is this. The mobile terminal 5 also includes personal digital assistants (PDAs), handheld computers, personal computers, multiprocessor systems, microprocessor-based or programmable consumer electronics, network PCs and wearables. Type computers and the like.

The mobile terminal 5 may comprise more components than the components shown in FIG. However, the components shown are sufficient to disclose an exemplary embodiment for implementing the invention. As shown in FIG. 5, the mobile terminal 5 includes a processing unit (CPU) 12, a memory 48, a RAM 16, a ROM 32, an operating system 20, and an access point table maintaining module ( 30, programs 34, data storage 36, ranking processing module 38, BIOS 18, power supply 26, input / output interface 24, wireless interface 10a, optional 2 wireless interface 10b, illuminator 50, tactile interface 52, audio interface 54, display 56, keypad 58, infrared input / output interface 60, and satellite positioning system (global positioning system (GPS) receiver 62.

The mobile terminal 5 may selectively communicate with a wireless access point or base station (not shown) or directly with other mobile devices via the air interface 10a and / or 10b. The air interfaces 10a and 10b include circuitry for connecting the mobile terminal 5 to several wireless networks, and include global system for mobile communications (GSM), code division multiple access. ; CDMA), Institute of Electrical and Electronics Engineers (IEEE) 802.11, IEEE 802.16 (WiMax), user datagram protocol (UDP), transmission control protocol / Internet protocol Several communications, including but not limited to Internet protocol (TCP / IP), short message service (SMS), general packet radio service (GPRS), and wireless application protocol (WAP), and the like. It is configured for use with the protocol.

The mass storage memory 48 generally includes a RAM 16, a ROM 32, and one or more data storage units 36. Mass storage memory 48 as mentioned above illustrates a type of computer readable media, ie, computer storage media. Computer storage media may include volatile and non-volatile, removable and non-removable media implemented in any method or technology for storing information such as computer readable instructions, data structures, program modules or other data. Can be. Examples of computer storage media include RAM, ROM, EEPROM, flash memory or other semiconductor memory technology, CD-ROMs, digital versatile disks (DVDs) or other optical storage devices, magnetic cassettes, magnetic tapes, magnetic disk storage or There are other magnetic storage devices or other media that can be used to store the desired information and can be accessed by the computing device. The data storage 36 is in particular a mobile terminal for storing programs 34, access point table maintenance module 30, ranking processing module 38, databases and / or libraries of images, lists and other data. 30 may be employed.

The mass storage memory stores an operating system 20 that controls the operation of the mobile terminal 5. It can be appreciated that these components can include general purpose operating systems such as versions of UNIX or LINUX ^™ , or dedicated mobile communication operating systems such as the Symbian ^® operating system. A basic input / output system (BIOS) 18 is also provided for controlling the low level operation of the mobile terminal 5. The mass storage memory also stores application code and data used by the mobile terminal 5. More specifically, mass storage memory 48 stores access point table maintenance module 30, programs 34, and ranking processing module 38. The modules may include computer executable instructions that may be executed under the control of the operating system 20 to prioritize and otherwise control communication with wireless access points, base stations, and / or other mobile terminals. In addition, the programs 34, when executed by the mobile terminal 5, transmit and receive WWW pages, e-mail, audio and video, and enable remote communication with another user of another mobile device. It may include computer executable instructions.

The mobile terminal 5 also includes an input / output interface 24 that communicates with external devices such as a headset, or other input or output devices, not shown in FIG. Keypad 58 may include any input device configured to receive input from a user. For example, keypad 58 may include a push button numeric dial, or a keyboard. Keypad 58 may also include command buttons associated with the selection and transmission of images. The display 56 may be a liquid crystal display (LCD), a gas plasma display, a light emitting diode (LED) display, or other type of display used with a mobile device. Display 56 may also include a touch screen configured to receive input from an object, such as a human finger or stylus. In addition, infrared input / output 60 may be used to send and receive infrared commands to / from other devices.

The power source 26 provides power to the mobile terminal 5. Rechargeable or non-rechargeable batteries can be used to provide power. The power may also be provided by an external power source, such as an powered docking cradle that charges and / or supplements an AC adapter or battery.

As shown, the mobile terminal 5 includes an illuminator 50, a tactile interface 52, and an audio interface 54. Illuminator 50 may be in response to events or in an operational state for a particular time period. For example, when illuminator 50 is in an active state, the illuminator 50 may illuminate the buttons on keypad 59 with backlight and remain active while the mobile device is powered up. In addition, illuminator 50 may backlight these buttons in various patterns when certain actions are performed, such as dialing of another mobile device. Illuminator 50 also allows light sources disposed within the transparent or translucent case of the mobile device to provide illumination in response to various actions. The tactile interface 52 is adapted to provide contact feedback to the user of the mobile terminal. For example, the tactile feedback can be employed to vibrate the mobile terminal 5 in a particular way when another user of the mobile terminal makes a call. The audio interface 54 is configured to generate and receive audio signals such as human voice. For example, audio interface 54 may be coupled to speakers and microphones (not shown) to enable remote communication with others and / or to generate audio responses to certain actions.

The satellite positioning system (GPS) receiver 62 may determine the actual coordinates of the mobile terminal 5 on the surface of the earth, which may be provided to the geographical address program in latitude and longitude coordinates. These coordinates can include latitude, longitude and altitude. The Global Positioning System (GPS) is operated by the US Department of Defense to provide worldwide navigation, location, and accurate timing services. The satellite positioning system (GPS) includes a worldwide satellite network that interacts with the satellite positioning system receiver 62 to allow a geographical address application to accurately determine the location of the mobile terminal 5. This position is typically output from the satellite positioning system (GPS) receiver 62 as latitude and longitude values. The satellite positioning system (GPS) receiver 62 also performs triangulation, assisted GPS (AGPS), E to additionally determine the actual position, velocity, acceleration, and / or other characteristics of the mobile terminal 5 on the earth's surface. Other geolocation mechanisms may be employed, including but not limited to ODT, CI, SAI, ETA, BSS, etc. It will be appreciated that under other conditions, the GPS positioning receiver 62 can determine the actual position within millimeters with respect to the mobile terminal 5, in other cases the determined actual position is 1 meter or significantly. It may be less accurate, such as within long distances.

2 is a functional block diagram illustrating an enterprise configuration of functional elements for a representative embodiment of the present invention. Mobile terminals 5a, 5n respectively establish wireless communication with one or more wireless access points, such as wireless local area network (WLAN) access points 92a, 92b, and / or 92n. Wireless communication may be accomplished with a number of wireless communication technologies and / or protocols, including IEEE 802.11, IEEE 802.16, Bluetooth ^™ , infrared and the like. Each mobile terminal may detect one or more wireless access points if they are within the coverage area of the one or more access points. For example, the mobile terminal 5a may detect the wireless access points 92a and 92b because the mobile terminal 5a is inherent in the wireless communication enabled areas 94a and 94b, respectively. to be. Thus, the wireless access points 92a and 92b are referred to as detected wireless access points with respect to the mobile terminal 5a. The neighboring wireless access points may provide a neighboring communicable area that is adjacent to or overlaps the communicable area of the detected wireless access point. However, neighboring wireless access points are not yet detected by the mobile terminal. For example, wireless access point 92n is a neighboring wireless access point for mobile terminal 5a. The mobile terminal 5a has not yet detected a neighboring wireless access point 92n because the mobile terminal 5a is not yet inherent in the neighboring wireless access point communicable area 94n.

Both detected wireless neighbors and neighboring wireless access points are in communication with a call quality manager (CQM) 140. Communication with the call quality manager (CQM) 140 may be implemented in a number of ways via a wireless local area network (WLAN) switch 96, intranet 130, and the like. The call quality manager (CQM) 140 may include one or more network nodes such as routers and servers and the like. The call quality manager (CQM) 140 may include a number of components, including a call quality manager (CQM) communication interface 142 for communicating with the wireless access points. Call quality manager (CQM) 140 may further include a call quality manager (CQM) CPU 144 for executing machine instructions stored in call quality manager (CQM) memory 146. The machine instructions include instructions for obtaining and evaluating wireless access points and / or status data regarding overall network performance. The call quality manager (CQM) 140 may also provide other network monitoring and management functions.

The wireless access points may communicate status data from the call quality manager (CQM) 140 to the mobile terminals and may receive status reports from the mobile terminals. The wireless access points also allow communication between mobile nodes and other nodes, including wired communication devices. For example, the mobile terminals 5a and / or 5b may be voice over internet via a session initiation protocol (SIP) aware firewall 134 and through the public internet 150. protocol (VOIP) telephone 125. Voice communication and data communication are possible between the mobile terminals and between the mobile terminals and other nodes such as voice (VOIP) phone 125 and other computing devices over the Internet protocol.

3 is a flow diagram illustrating exemplary logic for controlling communication between a mobile terminal and one or more wireless access points. In operation 160, the mobile terminal registers with the call quality manager CQM as it enters a callable area of a wireless access point networked with the call quality manager CQM. Loop operation 162 is performed for each wireless access point currently detected by the mobile terminal. In operation 164, the mobile terminal obtains link state data from the detected access point and / or detects link state data through its mobile communication interface. Link state data includes received signal strength indication (RSSI), data rate, bandwidth, channel, encoder / decoder identifier, round trip time, jitter value, packet loss value, packet information and voice information. And the like. Based on link state data, the mobile terminal determines link quality with respect to the communication link having the detected wireless access point in operation 166. The link quality may be a numerical value, a level indicator (eg red, yellow, blue), or other measure. In loop termination operation 168, the mobile terminal determines whether another wireless access point is currently detected by the mobile terminal, thereby obtaining link state data from the next currently detected wireless access point. Return control is made.

If link state data and link quality data have been obtained and determined for all wireless access points currently detected by the mobile terminal, the mobile terminal generates a mobile terminal report in operation 170. The mobile terminal report may include link state data and link quality data. The mobile terminal report may also include a terminal priority list that determines the ranking of communication links with the wireless access points. The terminal priority list is determined as a function of link quality data and / or link state data determined for each currently detected wireless access point. Table 1 below provides a sample mobile terminal report.

Access point identifier RSSI quality Data rate channel Priority 00: E0: 0B: F5: 62: 08 -83 ㏈ 15/19 11 Mbps 6 One 00: 04: 59: 8A: 09: 3C -90 ㏈ 13/19 5.5 Mbps 11 2

In operation 172, the mobile terminal delivers a mobile terminal report to the call quality manager (CQM). The mobile terminal report may be sent to the call quality manager (CQM) at a variable rate depending on available bandwidth, resolution of data, and / or other factors. For example, mobile terminal reports may not be sent frequently if the mobile terminal is not in a voice call. In contrast, mobile terminal reports may be sent more frequently when the mobile terminal is in a voice call. The call quality manager (CQM) uses the terminal report to obtain additional status information and to perform further evaluation of the wireless access points. More details will be described below with respect to FIG. 4.

In operation 174, the mobile terminal receives the call quality manager (CQM) report from one of the currently detected wireless access points from a call quality manager (CQM). The Call Quality Manager (CQM) report includes additional status data regarding network access and wireless access point that may or may not be detectable by the mobile terminal. The call quality manager (CQM) report may also include call quality manager (CQM) priorities (other than the terminal priority list). The call quality manager (CQM) ranking of wireless access points may include one or more neighboring wireless access points that are not currently detectable by the mobile terminal. The mobile terminal can optionally determine the current position, velocity, acceleration, and / or other movement characteristics in optional operation 176. Based on the mobile characteristics, the mobile terminal may determine which of the wireless access points listed in the call quality manager (CQM) report are closest to the mobile terminal and / or the call quality manager (CQM). ) Can predict which of the wireless access points listed in the report are likely to be detectable by the mobile terminal in the shortest amount of time. The mobility characteristics and predictions can be made by comparing multiple terminal reports and / or call quality manager (CQM) reports over a predetermined time period. In operation 178, the mobile terminal determines an overall priority list of wireless access points such that the mobile terminal determines the best wireless access point during current or prior communication. The determination of the best wireless access point takes into account the nearest wireless access point, as well as other states and characteristics of each wireless access point that may or may not be available directly to the mobile terminal. For example, current load data may not be available directly to the mobile terminal. Instead, the mobile terminal can obtain such data from a call quality manager (CQM) report.

Once the mobile terminal has determined the overall priority list, the mobile terminal determines in decision step 180 whether the previously selected wireless access point is still the best choice for precommunication. If the previously selected wireless access point is still determined to be the highest rank in the overall priority list, return to loop operation 16 to obtain status data and repeat the process of evaluating the quality for each of the wireless access points. Control is made. However, if the preselected wireless access point is no longer the highest ranked wireless access point, the mobile terminal initiates a communication handoff for the highest ranked wireless access point in operation 182.

4 is a flow diagram illustrating exemplary logic for a call quality manager for evaluating wireless access points associated with mobile terminals. In operation 190, the call quality manager CQM sets up a list of all wireless access points that may be in communication with the call quality manager CQM. The call quality manager (CQM) registers each mobile terminal detected by the wireless access point in operation 192. In loop operation 194, the call quality manager (CQM) begins to collect and process status and quality data related to each wireless access point that may be associated with a mobile terminal. In operation 196, the wireless access point receives a mobile terminal report and relays the mobile terminal report to the call quality manager (CQM). It is to be considered here that the mobile terminal report can be received by any of the wireless access points that detect the mobile terminal, not just the wireless access point currently used by the mobile terminal for advance communication. In operation 198, the call quality manager (CQM) reads the mobile terminal report to determine which wireless access points are currently detected by the mobile terminal.

The call quality manager (CQM) then obtains status data for each of the wireless access points detected by the mobile terminal by the current detector and listed in the mobile terminal report. State data may include communication performance, current load, security state and capabilities, corrupted voice packets, re-ordered voice packets, average latency, and the like. The state data also includes an admission policy indicating whether the wireless access point has the capability to allow new calls to be made, and a roaming indicating whether the wireless access point has the capability to support existing calls to roam. Policy information such as a policy and lifeline policy indicating whether the wireless access point has the capability to support last resort cellular handoff efforts. .

In operation 200, the call quality manager (CQM) determines neighboring access points for wireless access points that are listed on the mobile terminal as detected by the mobile terminal. The neighboring wireless access point provides a neighboring communicable area adjacent to the detected wireless access point communicable area or overlapping the detected wireless access point communicable area, but the neighboring wireless access point is not yet provided by the mobile terminal. Not detectable. The call quality manager (CQM) then obtains state data for each of the neighboring wireless access points. Based on the detected wireless access points and state data of the neighboring wireless access points, the call quality manager (CQM) determines quality data and ranks the wireless access points. The call quality manager (CQM) then generates a call quality manager (CQM) report in operation 202. The call quality manager (CQM) report may include status data, call quality manager (CQM) priorities, and other related data. Table 2 below illustrates a sample of the Call Quality Manager (CQM) report.

Access point identifier Load Priority Policy 00: E0: 0B: F5: 62: 08 95% 3 Approvals: N, Loum: N, Lifeline: N 00: 04: 59: 8A: 09: 3C 55% One Approval: Y, Loum: Y, Lifeline: Y 00: F6: 81: 45: 02: 7B 35% 2 Approval: Y, Loum: Y, Lifeline: Y

In operation 204, the call quality manager (COM) may use a call quality manager (CQM) report to determine the overall priority list of wireless access points and to select the best wireless access point. Send a Manager (CQM) report. The call quality manager (CQM) then loops in a loop termination operation 206 so that the other mobile terminal is detected by one of the wireless access points to process the other mobile terminal report and evaluate the associated wireless access points. It is determined whether control to return to operation 194 is made.

The above mentioned specifications, examples and data are intended to provide a complete description of the manufacture and use of the structures of the present invention. Since various embodiments of the invention can be made without departing from the spirit and scope of the invention, the invention resides in what is set forth in the claims appended hereto.

Claims (22)

In the method for controlling wireless communication with a plurality of wireless access points, The method, (a) determining link quality data about each communication link between the mobile terminal and each detected wireless access point, wherein each detected wireless asymptote is currently detectable by the mobile terminal; (b) determining access point quality data for each detected wireless access point; And (c) selecting the best wireless access point to communicate with the mobile terminal as a function of the link quality data and the access point quality data, wherein the best wireless access point is at least from the detected wireless access point. The method comprising the step of being selected. The method of claim 1, The method, (a) including at least one of a state and a quality assessment of a neighboring wireless access point in access point quality data, wherein the neighboring wireless access point is adjacent to the detected wireless access point communicable area or detected wireless access point communication; Providing a neighboring coverage area that overlaps the coverage area, but wherein the neighboring wireless access point is not yet detectable by the mobile terminal; And (b) selecting the best wireless access point from the detected wireless access points and the neighboring wireless access point. The method of claim 1, Determining the link quality data, (a) determining link state data indicative of the state of each communication link between said mobile terminal and each detected wireless access point; And (b) determining a link quality for each communication link with each detected wireless access point. 3. The method of claim 2, wherein the link state data is determined by one of the mobile terminal and each detected wireless access point. The method of claim 2, The method, (a) generating a mobile terminal report comprising at least one of a terminal priority list comprising the ranks of communication links having detected wireless access points determined by the mobile terminal and the link quality data; And (b) forwarding the mobile terminal report to a central computing device that is in communication with the detected wireless access point and the neighboring wireless access point, respectively. The method of claim 2, Determining the access point quality data, (a) causing the central computing device to obtain access point state data from each detected wireless access point and from the neighboring wireless access point; (b) causing the central computing device to rank the neighboring wireless access point and each detected wireless access point as a function of the access point state data; And (c) causing the central computing device to communicate the access point state data and the ranking to the mobile terminal as the access point quality data. The method of claim 2, To choose the best wireless access point, (a) receiving the access point quality data from a central computing device in communication with the detected wireless access points and the neighboring wireless access point; (b) determining an overall priority of the neighboring wireless access points and the detected wireless access points; And (c) determining whether a previously selected wireless access point from the detected wireless access points used for prior communication by the mobile terminal maintains a first priority. The method of claim 2, The method, (a) detecting movement of the mobile terminal with respect to the detected wireless access point and the neighboring wireless access point, respectively; And (b) predicting the best wireless access point as a function of the movement. The method of claim 1, The method, Initiating a handover of communication from a previously selected wireless access point to the best wireless access point, wherein the mobile terminal uses the previously selected wireless access point for precommunication. How to. 2. The method of claim 1, wherein the link quality data comprises at least one of signal length, data rate, round trip time, encoder / decoder identifier, jitter value, and packet loss value. The network of claim 1, wherein the access point quality data includes performance, load, packet loss value, packet reordering value, latency, admission capability to allow new communication, roaming performance to support roaming of existing communication, and another network. And at least one of a lifeline handoff capability to support rerouting communication for the wireless access point, and a recommended wireless access point. A mobile terminal for controlling wireless communication with a plurality of wireless access points, The mobile terminal, (a) a wireless communication interface; (b) a processor for communicating with the wireless communication interface; (c) a memory in communication with the processor, the processor comprising:    (i) determining link quality data for each communication link between the mobile terminal and each detected wireless access point, wherein each detected wireless access point is currently detectable through an air interface of the mobile terminal;    (ii) acquiring access point quality data for each detected wireless access point; And    (iii) selecting the best wireless access point to communicate with the mobile terminal as a function of the link quality data and the access point quality data, wherein the best wireless access point is selected from at least the detected wireless access points; And a memory for storing machine instructions for causing a plurality of actions to be performed, including the acts of being acted upon. The method of claim 12, wherein the machine instructions stored in the memory further include: The processor, (a) incorporating at least one of a state and quality assessment of a neighboring wireless access point into access point quality data, wherein the neighboring wireless access point is adjacent to the detected wireless access point communicable area or detected wireless access point communication; Providing a neighboring coverage area that overlaps a coverage area, but wherein the neighboring wireless access point is not yet detectable by the mobile terminal; And and (b) selecting the best wireless access point from the detected wireless access points and the neighboring wireless access point. The method of claim 11, wherein the machine instructions stored in the memory are also: The processor, (a) determining link state data indicative of the state of each communication link between said mobile terminal and each detected wireless access point; And (b) perform a function of determining link quality for each communication link with each detected wireless access point. The method of claim 13, wherein the machine instructions stored in the memory are also: The processor, (a) generating a mobile terminal report comprising at least one of a terminal priority list comprising a priority list of detected wireless access points and the link quality data; And and (b) forwarding the mobile terminal report to a central computing device that is in communication with the detected wireless access point and the neighboring wireless access point, respectively. The method of claim 13, wherein the machine instructions stored in the memory are also: The processor, (a) receiving the access point quality data from a central computing device in communication with the detected wireless access points and the neighboring wireless access point; (b) determining an overall priority of the neighboring wireless access points and the detected wireless access points; And (c) perform a function of determining whether a previously selected wireless access point maintains a first priority. The method of claim 12, wherein the machine instructions stored in the memory are also: The processor, And initiate a handover of a communication from a previously selected wireless access point to the best wireless access point. 13. The mobile terminal of claim 12, wherein the link quality data comprises at least one of signal length, data rate, round trip time, encoder / decoder identifier, jitter value, and packet loss value. 13. The method of claim 12, wherein the access point quality data includes performance, load, packet loss value, packet reordering value, latency, admission capability to allow new communication, roaming performance to support roaming of existing communication, and another network. And at least one of a lifeline handoff capability to support rerouting communications for a wireless access point, and a recommended wireless access point. A system for providing access point quality data to a mobile terminal, The system, (a) a communication interface in communication with a plurality of wireless access points including detected wireless access points and neighboring wireless access points, wherein the detected wireless access points are currently detected by the mobile terminal and the neighboring wireless A communication interface providing a communicable area not currently detected by the mobile terminal and overlapping a detected wireless access point communicable area adjacent to the detected wireless access point communicable area; (b) a processor for communicating with the communication interface; And (c) a memory in communication with the processor, the processor comprising:    (i) receiving link quality data about each communication link between the mobile terminal and each detected wireless access point;    (ii) determining a neighboring access point with respect to at least one of the detected wireless access points;    (iii) determining access point quality data for each detected wireless access point and the neighboring wireless access point; And    (iv) a memory for storing machine instructions for performing a plurality of actions including transferring said access point quality data to said mobile terminal via one of said detected wireless access points; system. The method of claim 20, wherein the machine instructions stored in the memory are further: The processor, (a) obtaining access point state data from each detected wireless access point and from the neighboring wireless access point; (b) determining a ranking of the neighboring wireless access point and each detected wireless access point as a function of the access point state data; And and (c) generate a report of access point quality data including said access point status data and respective ranks. 21. The method of claim 20, wherein the access point quality data includes performance, load, packet loss value, packet reordering value, latency, admission performance to allow new communication, roaming performance to support roaming of existing communications, and another network. At least one of a lifeline handoff capability to support rerouting communications for the wireless communication point, and a recommended wireless access point.

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