CA2411900C - Wlan having load balancing by access point admission/termination - Google Patents
Wlan having load balancing by access point admission/termination Download PDFInfo
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- CA2411900C CA2411900C CA002411900A CA2411900A CA2411900C CA 2411900 C CA2411900 C CA 2411900C CA 002411900 A CA002411900 A CA 002411900A CA 2411900 A CA2411900 A CA 2411900A CA 2411900 C CA2411900 C CA 2411900C
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- mobile station
- association
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04W—WIRELESS COMMUNICATION NETWORKS
- H04W48/00—Access restriction; Network selection; Access point selection
- H04W48/02—Access restriction performed under specific conditions
- H04W48/06—Access restriction performed under specific conditions based on traffic conditions
-
- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04L—TRANSMISSION OF DIGITAL INFORMATION, e.g. TELEGRAPHIC COMMUNICATION
- H04L45/00—Routing or path finding of packets in data switching networks
- H04L45/24—Multipath
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04L—TRANSMISSION OF DIGITAL INFORMATION, e.g. TELEGRAPHIC COMMUNICATION
- H04L5/00—Arrangements affording multiple use of the transmission path
- H04L5/02—Channels characterised by the type of signal
- H04L5/023—Multiplexing of multicarrier modulation signals
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04W—WIRELESS COMMUNICATION NETWORKS
- H04W48/00—Access restriction; Network selection; Access point selection
- H04W48/20—Selecting an access point
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- Computer Networks & Wireless Communication (AREA)
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Abstract
A network includes access points that admit/terminate mobile station associations based upon the loading level of the access point and/or whether a mobile station can associate with a further access point. Mobile stations transmit information indicative of the access points to which they can associate. The access points determine whether to admit/terminate a mobile station association based upon access point loading.
Description
WLAN HAVING LOAD BALANCING BY ACCESS POINT
ADMISSION/TERMINATION
FIELD OF THE INVENTION
The present invention relates generally to communication networks and, more particularly, to wireless communication networks.
BACKGROUND OF THE INVENTION
Wireless communication networks for providing links to mobile stations are well known in the art. In one type of wireless network, a series of access points provide wireless connections to various mobile users. For example, a building can include access points located at strategic locations to serve mobile users as they move throughout the building. The mobile users migrate from access point to access point based upon the strength of beacon signals from the various access points. That is, the mobile stations use the strength of the beacon signals to select the best access point at a given point in time.
With changes in the channel environment and number of users in a Wireless Local Area Network (WLAN) system, different access points experience different loading.
That is, the number of users served by each of the access points varies over time. Those access points that serve a relatively high number of stations (hot spots) can become overloaded and experience reduced performance. For example, an access point can become overloaded during a meeting in a conference room proximate the access point 2o when the attendees attempt to connect their laptops to the corporate intranet.
It would, therefore, be desirable to adjust the loading of network access points to reduce network congestion.
ADMISSION/TERMINATION
FIELD OF THE INVENTION
The present invention relates generally to communication networks and, more particularly, to wireless communication networks.
BACKGROUND OF THE INVENTION
Wireless communication networks for providing links to mobile stations are well known in the art. In one type of wireless network, a series of access points provide wireless connections to various mobile users. For example, a building can include access points located at strategic locations to serve mobile users as they move throughout the building. The mobile users migrate from access point to access point based upon the strength of beacon signals from the various access points. That is, the mobile stations use the strength of the beacon signals to select the best access point at a given point in time.
With changes in the channel environment and number of users in a Wireless Local Area Network (WLAN) system, different access points experience different loading.
That is, the number of users served by each of the access points varies over time. Those access points that serve a relatively high number of stations (hot spots) can become overloaded and experience reduced performance. For example, an access point can become overloaded during a meeting in a conference room proximate the access point 2o when the attendees attempt to connect their laptops to the corporate intranet.
It would, therefore, be desirable to adjust the loading of network access points to reduce network congestion.
2 SUMMARY OF THE INVENTION
The present invention provides a wireless network having access points with mobile station association admission/termination control for access point load balancing in accordance with the present invention. With this arrangement, overall network performance is enhanced by more efficient access point loading. While the invention is primarily shown and described in conjunction with wireless access points in an 802.11 network, it is understood that the invention is applicable to wireless networks in general in which it is desirable to distribute loading.
In one aspect of the invention, a wireless network includes a series of access l0 points to which mobile stations can associate. In the case where an access point becomes relatively heavily loaded, or overloaded, the access point can decline association requests from additional mobile stations. In addition, an access point may terminate an existing association under certain conditions, such as where an associated mobile station has the option to associate with a further access point.
15 In accordance with one aspect of the present invention there is provided a method of controlling access point loading in a wireless network, comprising:
receiving information transmitted by a mobile station to a first one of a plurality of access points, the information including an indication of one or more access points in the plurality of access points to which the mobile station can attempt to associate; and determining 20 whether to admit or terminate an association of the mobile station to the first one of the plurality of access points based upon a loading level of the first one of the plurality of access points and said received information.
In accordance with another aspect of the present invention there is provided an access point, comprising: a transceiver for providing communication with a mobile 25 station over a radio link; a memory for storing information including for one or more 2a mobile stations how many access points each of the one or more mobile stations can associate with; and an association module for determining whether to accept or terminate an association with a mobile station based upon a loading level of the access point and the stored information for the one or more mobile stations.
BRIEF DESCRIPTION OF THE DRAWINGS
The invention will be more fully understood from the following detailed description taken in conjunction with the accompanying drawings, in which:
FIG. 1 is a schematic depiction of a wireless network having access points that can decline/terminate mobile station associations in accordance with the present invention;
FIG. 2 is a schematic block diagram of an exemplary access point that can decline/terminate mobile station associations in accordance with the present invention;
FIG. 3 is a pictorial representation of an exemplary capability field that can be contained in a message exchanged by an access point. and a mobile station in accordance with the present invention;
FIG. 4A is a schematic depiction of a mobile station for associating with an access point that can decline/terminate associations in accordance with the present invention;
FIG. 4B is a schematic depiction of an access point that can decline/terminate associations in accordance with the present invention; and FIG. 5 is a schematic depiction of a network having an access point controller for t5 controlling loading of network access points in acc<jrdance with the present invention.
DETAILED DESCRIPTION OF THE INVENTION
FIG. 1 shows an exemplary vvireless network. I00 having access points that perform load balancing by access point admission control of mobile stations and/or termination of 2o mobile station associations. 'The network 100 includes a series of access points APa_N having associated coverage areas CA;,_P serving various mobile stations MSa_M. In general, each access point Apa_N evaluates its loading level to determine whether additional mobile station associations are feasible, e.g., would not result in (or make worse) an overload condition for the access point. In addition, an access paint can terminate a mobile station association 2s under certain conditions to distribute= access point loading. Fc~r example, a mobile station may transmit an indication to an overloaded access point that there are other access points to which the mobile station can associate itself. The overloaded access paint may terminate the association and the mobile station can attempt to associate with another access point having a lower traffic loading level.
For example, a relatively highly loaded access point, here shown as APa, can determine that it should not accept additional associations, such as from MSS.
Or this access point APa may terminate an association with the mobile stati~m MS~. In one embodiment, the access point terminates an association with the mobile station having the greatest number of access point options. This mobile, station MSC then looks for another access point, e.g., APh, to which an association request can be made, as described in detail below.
In an exemplary embodiment, after an association is terminated, the mobile station "remembers" which access point terminated the association and does not attempt to associate with that access point until a predetermined event occurs, e.g., a time interval expires, etc.
This prevents the mobile station from bouncing around between access points.
In one embodiment, the access points AP receive information from the mobile stations MS indicating how many access points each mobile station can "hear."
As used herein, a mobile station can "'hear" an access point if the associated beacon signal is received by the mobile station at or above a predetermined power level. However, further techniques, such as error rates, for evaluating a fink between an access point and a mobile station will be readily apparent to one of ordinary skill in the art.
It is understood that a determination as to whether an access point should accept an additional association or terminate an existing association can be based upon a wide variety of factors, including number of associated mobile stations, link bandwidth, expected traffic levels, traffic intensity, packet error rate, packet delay at the access point, and the measurement of the received signal power from a subset of stations. It is understood that these factors can be considered in a range of techniques, such as weighting selected factors.
It is further understood that the terra "mobile station," as used herein, should be construed broadly to include various, wireless devices, such as laptops, Personal Digital Assistants (PDAs), mobile phones, and the like. Similarly, the term "access point" should be broadly construed to include transmitters/receivers in general that can provide a radio link with a mobile station.
Before describing further details of the present invention, some basic concepts are now described. In conventional wireless networks having mobile stations served by various access points, such as in an 802.11 network, there is a standard procedure by which mobile stations associate themselves with an access point. The IEEE
802.11 standard is defined in International Standard ISO/IEC 8802-111, "Information Technology-Telecommunications and Information Exchange Area Networks," 1999 1o Edition. Before a mobile station associates with an access point, it obtains information of nearby access points by scanning the frequency channels for their beacons. The access points typically send out beacon frames periodically.
In traditional WLANs, such as 802.11 networks, beacon powers of access points are kept at a fixed level. The mobile station simply chooses the access point with the best signal strength for association. However, it is possible that one access point may be already overloaded, although it has the strongest signal strength to the mobile station.
While the following descriptions are applicable to 802.11 WLANs, it is understood that the invention applies to wireless networks in general using similar formats and mechanisms. Table 1 below shows the beacon frame body of a management 2o frame of subtype Beacon with each of the listed components specified in the 802.11 standard.
'table 1. Beacon frame body Order Information Notes _ _ 1 Timestam _- ~_'l'ime/da~/ etc_information _-,-2 Beacon interval __ ~ "Time between b_ea_con intervals _ _
The present invention provides a wireless network having access points with mobile station association admission/termination control for access point load balancing in accordance with the present invention. With this arrangement, overall network performance is enhanced by more efficient access point loading. While the invention is primarily shown and described in conjunction with wireless access points in an 802.11 network, it is understood that the invention is applicable to wireless networks in general in which it is desirable to distribute loading.
In one aspect of the invention, a wireless network includes a series of access l0 points to which mobile stations can associate. In the case where an access point becomes relatively heavily loaded, or overloaded, the access point can decline association requests from additional mobile stations. In addition, an access point may terminate an existing association under certain conditions, such as where an associated mobile station has the option to associate with a further access point.
15 In accordance with one aspect of the present invention there is provided a method of controlling access point loading in a wireless network, comprising:
receiving information transmitted by a mobile station to a first one of a plurality of access points, the information including an indication of one or more access points in the plurality of access points to which the mobile station can attempt to associate; and determining 20 whether to admit or terminate an association of the mobile station to the first one of the plurality of access points based upon a loading level of the first one of the plurality of access points and said received information.
In accordance with another aspect of the present invention there is provided an access point, comprising: a transceiver for providing communication with a mobile 25 station over a radio link; a memory for storing information including for one or more 2a mobile stations how many access points each of the one or more mobile stations can associate with; and an association module for determining whether to accept or terminate an association with a mobile station based upon a loading level of the access point and the stored information for the one or more mobile stations.
BRIEF DESCRIPTION OF THE DRAWINGS
The invention will be more fully understood from the following detailed description taken in conjunction with the accompanying drawings, in which:
FIG. 1 is a schematic depiction of a wireless network having access points that can decline/terminate mobile station associations in accordance with the present invention;
FIG. 2 is a schematic block diagram of an exemplary access point that can decline/terminate mobile station associations in accordance with the present invention;
FIG. 3 is a pictorial representation of an exemplary capability field that can be contained in a message exchanged by an access point. and a mobile station in accordance with the present invention;
FIG. 4A is a schematic depiction of a mobile station for associating with an access point that can decline/terminate associations in accordance with the present invention;
FIG. 4B is a schematic depiction of an access point that can decline/terminate associations in accordance with the present invention; and FIG. 5 is a schematic depiction of a network having an access point controller for t5 controlling loading of network access points in acc<jrdance with the present invention.
DETAILED DESCRIPTION OF THE INVENTION
FIG. 1 shows an exemplary vvireless network. I00 having access points that perform load balancing by access point admission control of mobile stations and/or termination of 2o mobile station associations. 'The network 100 includes a series of access points APa_N having associated coverage areas CA;,_P serving various mobile stations MSa_M. In general, each access point Apa_N evaluates its loading level to determine whether additional mobile station associations are feasible, e.g., would not result in (or make worse) an overload condition for the access point. In addition, an access paint can terminate a mobile station association 2s under certain conditions to distribute= access point loading. Fc~r example, a mobile station may transmit an indication to an overloaded access point that there are other access points to which the mobile station can associate itself. The overloaded access paint may terminate the association and the mobile station can attempt to associate with another access point having a lower traffic loading level.
For example, a relatively highly loaded access point, here shown as APa, can determine that it should not accept additional associations, such as from MSS.
Or this access point APa may terminate an association with the mobile stati~m MS~. In one embodiment, the access point terminates an association with the mobile station having the greatest number of access point options. This mobile, station MSC then looks for another access point, e.g., APh, to which an association request can be made, as described in detail below.
In an exemplary embodiment, after an association is terminated, the mobile station "remembers" which access point terminated the association and does not attempt to associate with that access point until a predetermined event occurs, e.g., a time interval expires, etc.
This prevents the mobile station from bouncing around between access points.
In one embodiment, the access points AP receive information from the mobile stations MS indicating how many access points each mobile station can "hear."
As used herein, a mobile station can "'hear" an access point if the associated beacon signal is received by the mobile station at or above a predetermined power level. However, further techniques, such as error rates, for evaluating a fink between an access point and a mobile station will be readily apparent to one of ordinary skill in the art.
It is understood that a determination as to whether an access point should accept an additional association or terminate an existing association can be based upon a wide variety of factors, including number of associated mobile stations, link bandwidth, expected traffic levels, traffic intensity, packet error rate, packet delay at the access point, and the measurement of the received signal power from a subset of stations. It is understood that these factors can be considered in a range of techniques, such as weighting selected factors.
It is further understood that the terra "mobile station," as used herein, should be construed broadly to include various, wireless devices, such as laptops, Personal Digital Assistants (PDAs), mobile phones, and the like. Similarly, the term "access point" should be broadly construed to include transmitters/receivers in general that can provide a radio link with a mobile station.
Before describing further details of the present invention, some basic concepts are now described. In conventional wireless networks having mobile stations served by various access points, such as in an 802.11 network, there is a standard procedure by which mobile stations associate themselves with an access point. The IEEE
802.11 standard is defined in International Standard ISO/IEC 8802-111, "Information Technology-Telecommunications and Information Exchange Area Networks," 1999 1o Edition. Before a mobile station associates with an access point, it obtains information of nearby access points by scanning the frequency channels for their beacons. The access points typically send out beacon frames periodically.
In traditional WLANs, such as 802.11 networks, beacon powers of access points are kept at a fixed level. The mobile station simply chooses the access point with the best signal strength for association. However, it is possible that one access point may be already overloaded, although it has the strongest signal strength to the mobile station.
While the following descriptions are applicable to 802.11 WLANs, it is understood that the invention applies to wireless networks in general using similar formats and mechanisms. Table 1 below shows the beacon frame body of a management 2o frame of subtype Beacon with each of the listed components specified in the 802.11 standard.
'table 1. Beacon frame body Order Information Notes _ _ 1 Timestam _- ~_'l'ime/da~/ etc_information _-,-2 Beacon interval __ ~ "Time between b_ea_con intervals _ _
3 Ca ability information fZ~,a_ource parameters, p«Iling parameters, etc.
4 SSID Service Set ID (Wireless N_et_wo_rk_Name) _ Su orted rates _--_ f)ata Rates syorted by the system/device 6 FH Parameter Set °rhe FI-1 Parameter Set inforrrration element is present within Beacon ti~ames generated by STAB
i.Mobile STAtions) using i'requency-hopping (FH) . ~ PHYs (PHYsical. Layer modulations) 7 DS Parameter Set . '-rhe DS Parameter Set information element is present within Bacon frames generated by STAs _ _ -using direct aeqiaence (DS) PI-IYs 8 CF Parameter Set ' he CF (Contention Free) Parameter Set information element is only present within Beacon frames generated by APs (Access Points) -~su ~ortin a PC.E~ (Po_in_t Coordination Function) 9 IBSS Parameter Set The IBSS (Indelre.ndent Basic Service Set) Parameter Set intorrnation element is only present within Beacon frames generated by STAB in an _. ~..._ _ _____~-___._______________-_._ TTM 'The TIM (Traffic Information Map) information i ~;lement is only laresent within Beacon frames _ _.-___-_.___. _. °enerated. by_APs._._ ___.._._._.__-__.._.._._ .~ -_ Typically, the mobile station cazn operate in either Passive Scanning mode or Active Scanning mode. In Passive Scanning mode, the mobile station listens to each channel scanned for no longer than a maximum duration defined by the ChannelTime parameter.
i.Mobile STAtions) using i'requency-hopping (FH) . ~ PHYs (PHYsical. Layer modulations) 7 DS Parameter Set . '-rhe DS Parameter Set information element is present within Bacon frames generated by STAs _ _ -using direct aeqiaence (DS) PI-IYs 8 CF Parameter Set ' he CF (Contention Free) Parameter Set information element is only present within Beacon frames generated by APs (Access Points) -~su ~ortin a PC.E~ (Po_in_t Coordination Function) 9 IBSS Parameter Set The IBSS (Indelre.ndent Basic Service Set) Parameter Set intorrnation element is only present within Beacon frames generated by STAB in an _. ~..._ _ _____~-___._______________-_._ TTM 'The TIM (Traffic Information Map) information i ~;lement is only laresent within Beacon frames _ _.-___-_.___. _. °enerated. by_APs._._ ___.._._._.__-__.._.._._ .~ -_ Typically, the mobile station cazn operate in either Passive Scanning mode or Active Scanning mode. In Passive Scanning mode, the mobile station listens to each channel scanned for no longer than a maximum duration defined by the ChannelTime parameter.
5 The Active Scanning mode involves the generation of a Probe Request frame by the mobile stations, which is shown in Table 2 below, and the subsequent processing of a received Probe Response frame, which is shcywn in Table 3, by the access point.
Table ~'.. Probe Kequet frame body Orde,-..... _Informationw__...._____ 1 _ S_S In -_ ~_-_ __ 2- _._ _~L~P°rted.rates______ .
Table 3. Probe Resuonse frame bodv OrderInformation _ ~ _ Notes- . _ _ 1 Timestamp _-,-_ Tirne/d~etc.._int_ormation __-~i_ 2 Beacon interval __ ~rirue between beacon intervals __ 3 Ca abilit informationReaourc~aramet~rs~ollin~~arameters, _ etc.
4 ______ _ __ Service Set ID_(Wireless Network SSID Name) ' __ data Rates au orted by the .s~~,s~tem/device ~ _ Su orted rates
Table ~'.. Probe Kequet frame body Orde,-..... _Informationw__...._____ 1 _ S_S In -_ ~_-_ __ 2- _._ _~L~P°rted.rates______ .
Table 3. Probe Resuonse frame bodv OrderInformation _ ~ _ Notes- . _ _ 1 Timestamp _-,-_ Tirne/d~etc.._int_ormation __-~i_ 2 Beacon interval __ ~rirue between beacon intervals __ 3 Ca abilit informationReaourc~aramet~rs~ollin~~arameters, _ etc.
4 ______ _ __ Service Set ID_(Wireless Network SSID Name) ' __ data Rates au orted by the .s~~,s~tem/device ~ _ Su orted rates
6 FH Parameter The FH Parameter Set information Set element is present within Beacon frames generated by STAB
_.. rr,iy fr~ec uen~ hoping PHYs __.
_.. rr,iy fr~ec uen~ hoping PHYs __.
7 DS Parameter 'i'he DS Parameter Set information Set element is present withitr Beacon frames generated by STAB
,using direct s~uencv PHYs
,using direct s~uencv PHYs
8 CF Parameter i The CF Parameter Se.t information Set element is only present within Beacon fran ues generated by APs '~rpPOrti~a PCF_-______--~
9 ~ ...
IBSS Parameter .
Set ~ 'The IBSS Parameter Set information element is j only present within Beacon frames generated by STAB in an IBSS
After scanning the access point beacons, the mobile station adopts the BSSID
(Basic Service Set ID: Access Point ID) and channel synchronization information in a Beacon 5 (passive) or Probe Response (active) coming from the <rccess point with the best signal strength. An Association/Reassociation Request is then issued by the. mobile station as it attempts to associate with the selectr-~d access point. The access point then responds with an Association Response. The corresponding Association Request and Association Response frame formats are shown below in Table 4 and Table 5, respectively. It is understood that further actions, such as authentication, take place before or after the association phase.
Table 4. Association/Reassociation Request frame body Order I Information 1 __ _Capability information 2 Listen interval ___.. . _. _ . ~ 5 ~ __...__. __ ....__ __.__ _ _ 4___.._l ''u~horted rates- __ __ Table 5. Association Response-frame body Order Information I -_ C~bil~ information 2 Status c_ode_ _ ...~saa'i_atio_n 1D (A1D) __-4 . Supported rates In accordance with the present invention, an access point can admit/terminate mobile station associations based upon the loading level of the access point. The mobile station transmits information relating the number of access points that are available for association and the access points keep track of I~;~ading levels. Based upon mobile station options for association and access point loading, each access point accepts or rejects new association requests and selectively terminates existing associaxions tee optimize overall access point load levels.
FIG. 2 shows an exemplary access point 200 having a processor 202 for controlling the overall operation of the access point and a memory 2U4. T'he access point 200 further includes an association control module 206 for handling mobile station association t5 admission/termination., as described more fully below. The access point 200 can further include conventional components including a wireless interface '250 including one or more RF transceivers, a network interface 252 for interacting with a wired network, and an I/O
interface 254 for communicating with various components, such as peripheral equipment.
2o Referring again to FIG.1, some mobile stations, such as MSc, will report that they can hear not only the currently associated access point AP~, but also one or more additional access points APb. In general, mobile stations can "hear" an access point if the beacon signal from the access point has a received signal strength at or above a predetermined threshold.
Other mobile stations, e.g., MS~, wi li report. that they can only hear their current access point 25 AP~.
Due to a termination of an existing association between an access point, e.g., APa, and a mobile station, e.g., MSS, the mobile station MS~ can attempt to associate itself with a further access point, e.g., APh. This in turn reduces the load and traffic intensity over the current access point APB.
Referring now to FIG. 1 in conjunction with FIG. 2. the signal infor~rrration transmitted by the mobile station MSa.~ can be stored in the access point memory 204, such as in a database, which can store, for example, a list 204a of mobile stations and the access points that are available to each mobile station. The memory can also store a received signal to strength 204b for each mobile station/access point. For single access point mobile stations, e.g., MSe, the current access point APa can measure the received signal strength.
In an exemplary embodiment, frequency option information can be conveyed in the Association/Reassociation request frame, which is shown above in Tables 4 and S. These 15 two management frames contain the same Capability Information field, which is used to indicate requested or advertised capabilities. In an illustrative embodiment, the length of the Capability Information field is two octets.
FIG. 3 shows an exemplary Capability Information field 300 having sub fields of 2o ESS 300a, IBSS 300b, CFPollable 30'?c, CFPoII Request 302d, and Privacy 302e, together using five of the sixteen total bits. In an exemplary embodiment, three. bits form a further subtield APFC 300f used to indicate access points that a given mobile station can associate with in frequency channels other than the frequency for the currently communicating access point. The remaining bits 300g of the Capability Information field 300 are reserved.
In another embodiment the capability information field uses one bit to indicate whether there is an alternative access point with sufficient signal strength available to the mobile station and uses additional bits (e.g., two to three hits) to indicate the rough signal quality of the alternative access point(s). This information can he used later by the current access point to assess if the particular mobile is able to move to the alternative access point.
FIG. 4A show an exemplary mobile station 400 that can communicate access point signal information to network access points in accordance with the present invention. The mobile station 400 includes an association function 402 that determines the number of access points which the mobile station can associate with as included in the Capability Information field in the Association/Reassociation request Frame, thus conveying the information to the current access point, In one embodiment, the association function 402 t0 scans the frequency channels to deter°mine those access points fc~r which the received beacon signal is greater than a predetermined threshold, for example. For each access point beacon signal that is greater than the threshold. the mobile station can consider those access points as viable options in the event of an association request denial or association termination.
Later, this information can be kept updated by a reassociation function 404 via reassociation requests by the mobile when there is a change, e.g., another access point is no longer available for the mobile station. The reassociation function 404 can indicate the number of access points that the mobile station r;an potentially associate with as identified in the Capability Information field.
As shown in FIG. 4B, an exemplary access point 5C10 can include. a first local function 502 to assess t:he medium load condition, e.g., determine the number of mobile stations associated with the access point, their bandwidth usage. transmission queue length, number of error packets compared to the. total traffic, etc. The access point 500 can further include a second local function 504 to assess the likelihood that a currently associated mobile station can associate with a different access point. lilore particularly, the access point 500 evaluates whether the signal strength of a further access point to the mobile station is sufficient to enable migration to the further access paint based upon information in the mobile station database 204 of FIG. :', for example. 'The access point 500 can further include an association control module SOfi for determining whether to accept association requests and when to terminate current associations. as described above.
In an exemplary embadiment, an access point transmits a disassociation frame to a mobile station in the event that the access paint has determined that an association should be terminated to enhance the overall access point loading. The disassociation frame body can contain a reason code associated with tf~e termination. .An exemplary list of reason codes is set forth below in Table; 6.
Table 6 Reason Codes REASON CODE MEANIN(_~
__ _____.-.________________-___-__-__ 0 Reserved 1 Unspecified ..____-_-______-_______-_-2 Previous ai.~tlnentication invalid 3 Deauthenticated because sending station is leaving (or has left) IBSS or ESS
4 Disassociated due to inactivity Disassociated because AP is unable to handle all currently associated stations 6 . Class 2 frame ~eceived from non-authenticated station 7 ' Class frarn~v received from non--associated station __~_-__.____...
8 ____ __________.__.
______._____.___-__ Disassociai:ed because sending station is leaving (or has left) BSS
I
' 9 Station reqaiesting (re)assaciation with responding station and up ~i~
Reserved .__.__.____.____-__________ .
_____ _._________ _i _ __..___________-_____~-__ to Upon receiving the disassociaticm frame, the mobile station stores the reason code and the transmitting access point. The rr~abile station, through the association module 402 of 1~IG. 4A, for example, then attempts to associate with a further access paint.
However, the association module 402 will not subsequently attenopt to associate with the terminating access point. By remembering that a particular access point has terminated an association, the mobile station avoids sending association requests to that access point.
The mobile station can treat an access point that has denied an association request in a similar manner.
s It is understood that the mobile station can attempt to associate with a terminating/denying access point after a predetermined event, such as an expired time duration. A variety of other such events will be readily apparent to one of ordinary skill in the art.
In an alternative embodiment shown in FIG. 5, access point 1o association/termination decisions are controlled by a central access point controller 600 coupled to the access points 602a-N in the network. The controller 600 receives association and loading information from the access points 602 and evaluates the overall impact of requested mobile station association requests and mobile station association terminations for each access point to achieve optimal load balancing in the overall 15 network.
One skilled in the art will appreciate further features and advantages of the invention based on the above-described embodiments. Accordingly, the invention is not to be limited by what has been particularly shown and described, except as indicated by the appended claims.
IBSS Parameter .
Set ~ 'The IBSS Parameter Set information element is j only present within Beacon frames generated by STAB in an IBSS
After scanning the access point beacons, the mobile station adopts the BSSID
(Basic Service Set ID: Access Point ID) and channel synchronization information in a Beacon 5 (passive) or Probe Response (active) coming from the <rccess point with the best signal strength. An Association/Reassociation Request is then issued by the. mobile station as it attempts to associate with the selectr-~d access point. The access point then responds with an Association Response. The corresponding Association Request and Association Response frame formats are shown below in Table 4 and Table 5, respectively. It is understood that further actions, such as authentication, take place before or after the association phase.
Table 4. Association/Reassociation Request frame body Order I Information 1 __ _Capability information 2 Listen interval ___.. . _. _ . ~ 5 ~ __...__. __ ....__ __.__ _ _ 4___.._l ''u~horted rates- __ __ Table 5. Association Response-frame body Order Information I -_ C~bil~ information 2 Status c_ode_ _ ...~saa'i_atio_n 1D (A1D) __-4 . Supported rates In accordance with the present invention, an access point can admit/terminate mobile station associations based upon the loading level of the access point. The mobile station transmits information relating the number of access points that are available for association and the access points keep track of I~;~ading levels. Based upon mobile station options for association and access point loading, each access point accepts or rejects new association requests and selectively terminates existing associaxions tee optimize overall access point load levels.
FIG. 2 shows an exemplary access point 200 having a processor 202 for controlling the overall operation of the access point and a memory 2U4. T'he access point 200 further includes an association control module 206 for handling mobile station association t5 admission/termination., as described more fully below. The access point 200 can further include conventional components including a wireless interface '250 including one or more RF transceivers, a network interface 252 for interacting with a wired network, and an I/O
interface 254 for communicating with various components, such as peripheral equipment.
2o Referring again to FIG.1, some mobile stations, such as MSc, will report that they can hear not only the currently associated access point AP~, but also one or more additional access points APb. In general, mobile stations can "hear" an access point if the beacon signal from the access point has a received signal strength at or above a predetermined threshold.
Other mobile stations, e.g., MS~, wi li report. that they can only hear their current access point 25 AP~.
Due to a termination of an existing association between an access point, e.g., APa, and a mobile station, e.g., MSS, the mobile station MS~ can attempt to associate itself with a further access point, e.g., APh. This in turn reduces the load and traffic intensity over the current access point APB.
Referring now to FIG. 1 in conjunction with FIG. 2. the signal infor~rrration transmitted by the mobile station MSa.~ can be stored in the access point memory 204, such as in a database, which can store, for example, a list 204a of mobile stations and the access points that are available to each mobile station. The memory can also store a received signal to strength 204b for each mobile station/access point. For single access point mobile stations, e.g., MSe, the current access point APa can measure the received signal strength.
In an exemplary embodiment, frequency option information can be conveyed in the Association/Reassociation request frame, which is shown above in Tables 4 and S. These 15 two management frames contain the same Capability Information field, which is used to indicate requested or advertised capabilities. In an illustrative embodiment, the length of the Capability Information field is two octets.
FIG. 3 shows an exemplary Capability Information field 300 having sub fields of 2o ESS 300a, IBSS 300b, CFPollable 30'?c, CFPoII Request 302d, and Privacy 302e, together using five of the sixteen total bits. In an exemplary embodiment, three. bits form a further subtield APFC 300f used to indicate access points that a given mobile station can associate with in frequency channels other than the frequency for the currently communicating access point. The remaining bits 300g of the Capability Information field 300 are reserved.
In another embodiment the capability information field uses one bit to indicate whether there is an alternative access point with sufficient signal strength available to the mobile station and uses additional bits (e.g., two to three hits) to indicate the rough signal quality of the alternative access point(s). This information can he used later by the current access point to assess if the particular mobile is able to move to the alternative access point.
FIG. 4A show an exemplary mobile station 400 that can communicate access point signal information to network access points in accordance with the present invention. The mobile station 400 includes an association function 402 that determines the number of access points which the mobile station can associate with as included in the Capability Information field in the Association/Reassociation request Frame, thus conveying the information to the current access point, In one embodiment, the association function 402 t0 scans the frequency channels to deter°mine those access points fc~r which the received beacon signal is greater than a predetermined threshold, for example. For each access point beacon signal that is greater than the threshold. the mobile station can consider those access points as viable options in the event of an association request denial or association termination.
Later, this information can be kept updated by a reassociation function 404 via reassociation requests by the mobile when there is a change, e.g., another access point is no longer available for the mobile station. The reassociation function 404 can indicate the number of access points that the mobile station r;an potentially associate with as identified in the Capability Information field.
As shown in FIG. 4B, an exemplary access point 5C10 can include. a first local function 502 to assess t:he medium load condition, e.g., determine the number of mobile stations associated with the access point, their bandwidth usage. transmission queue length, number of error packets compared to the. total traffic, etc. The access point 500 can further include a second local function 504 to assess the likelihood that a currently associated mobile station can associate with a different access point. lilore particularly, the access point 500 evaluates whether the signal strength of a further access point to the mobile station is sufficient to enable migration to the further access paint based upon information in the mobile station database 204 of FIG. :', for example. 'The access point 500 can further include an association control module SOfi for determining whether to accept association requests and when to terminate current associations. as described above.
In an exemplary embadiment, an access point transmits a disassociation frame to a mobile station in the event that the access paint has determined that an association should be terminated to enhance the overall access point loading. The disassociation frame body can contain a reason code associated with tf~e termination. .An exemplary list of reason codes is set forth below in Table; 6.
Table 6 Reason Codes REASON CODE MEANIN(_~
__ _____.-.________________-___-__-__ 0 Reserved 1 Unspecified ..____-_-______-_______-_-2 Previous ai.~tlnentication invalid 3 Deauthenticated because sending station is leaving (or has left) IBSS or ESS
4 Disassociated due to inactivity Disassociated because AP is unable to handle all currently associated stations 6 . Class 2 frame ~eceived from non-authenticated station 7 ' Class frarn~v received from non--associated station __~_-__.____...
8 ____ __________.__.
______._____.___-__ Disassociai:ed because sending station is leaving (or has left) BSS
I
' 9 Station reqaiesting (re)assaciation with responding station and up ~i~
Reserved .__.__.____.____-__________ .
_____ _._________ _i _ __..___________-_____~-__ to Upon receiving the disassociaticm frame, the mobile station stores the reason code and the transmitting access point. The rr~abile station, through the association module 402 of 1~IG. 4A, for example, then attempts to associate with a further access paint.
However, the association module 402 will not subsequently attenopt to associate with the terminating access point. By remembering that a particular access point has terminated an association, the mobile station avoids sending association requests to that access point.
The mobile station can treat an access point that has denied an association request in a similar manner.
s It is understood that the mobile station can attempt to associate with a terminating/denying access point after a predetermined event, such as an expired time duration. A variety of other such events will be readily apparent to one of ordinary skill in the art.
In an alternative embodiment shown in FIG. 5, access point 1o association/termination decisions are controlled by a central access point controller 600 coupled to the access points 602a-N in the network. The controller 600 receives association and loading information from the access points 602 and evaluates the overall impact of requested mobile station association requests and mobile station association terminations for each access point to achieve optimal load balancing in the overall 15 network.
One skilled in the art will appreciate further features and advantages of the invention based on the above-described embodiments. Accordingly, the invention is not to be limited by what has been particularly shown and described, except as indicated by the appended claims.
Claims (11)
1. A method of controlling access point loading in a wireless network, comprising:
receiving information transmitted by a mobile station to a first one of a plurality of access points, the information including an indication of one or more access points in the plurality of access points to which the mobile station can associate;
determining, by said first one of the plurality of access points, whether the mobile station can establish an association with a second one of the plurality of access points based on said received information; and determining whether to admit an association of the mobile station to the first one of the plurality of access points based upon a loading level of the first one of the plurality of access points and said determination of whether said mobile station can establish an association with said second one of the plurality of access points.
receiving information transmitted by a mobile station to a first one of a plurality of access points, the information including an indication of one or more access points in the plurality of access points to which the mobile station can associate;
determining, by said first one of the plurality of access points, whether the mobile station can establish an association with a second one of the plurality of access points based on said received information; and determining whether to admit an association of the mobile station to the first one of the plurality of access points based upon a loading level of the first one of the plurality of access points and said determination of whether said mobile station can establish an association with said second one of the plurality of access points.
2. The method according to claim 1, further including terminating an association between the mobile station and the first one of the plurality of access points and establishing an association between the mobile station and the second one of the plurality of access points.
3. The method according to claim 2, further including storing an identification of the first one of the plurality of access points.
4. The method according to claim 3, further including not requesting an association with the first one of the plurality of access points by the mobile station based upon the association termination.
5. The method according to claim 1, further including not requesting an association with the first one of the plurality of access points by the mobile station after being denied an association.
6. The method according to claim 1, further including receiving the information from the mobile station in an association request frame.
7. The method according to claim 6, further including receiving the information from the mobile station in a capability information subfield within the association request frame.
8. The method according to claim 1, further including storing the information in a database.
9. The method according to claim 1, further including determining the loading level of the first one of the plurality of access points by at least determining a number of currently associated mobile stations.
10. The method according to claim 1, further including determining a loading level of the first one of the plurality of access points by determining one or more of a number of currently associated mobile stations, link bandwidth, traffic levels, and a measurement of received signal power from a subset of mobile stations.
11. An access point, comprising:
a transceiver for providing communication with a mobile station over a radio link;
a memory for storing information including for one or more mobile stations how many and which access points each of the one or more mobile stations can associate with; and an association module for determining whether to accept an association with a mobile station based upon a loading level of the access point, the stored information, and a determination of whether said mobile station can establish an association with another access point.
a transceiver for providing communication with a mobile station over a radio link;
a memory for storing information including for one or more mobile stations how many and which access points each of the one or more mobile stations can associate with; and an association module for determining whether to accept an association with a mobile station based upon a loading level of the access point, the stored information, and a determination of whether said mobile station can establish an association with another access point.
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US7406319B2 (en) | 2008-07-29 |
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US20030134642A1 (en) | 2003-07-17 |
US7957742B2 (en) | 2011-06-07 |
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