TW201014397A - Mobile access in a diverse access point network - Google Patents

Abstract

Facilitating user terminal (UT) access to wireless networks having base stations (BSs) of disparate access types is described herein. In some aspects, BS parameterization is provided to facilitate search and/or access to distinct types of network BSs. For instance, parameters can modify a likelihood of identifying or remaining coupled to restricted access (RA) BSs in a home Node B (HNB) deployment. In other aspects of the subject disclosure, a PLMN ID reserved for HNBs is provided comprising multiple region IDs. Where a UT identifies a home region, HNBs can be given preference over macro BSs. Additionally, the UT can keep track of HNBs and HNB regions that reject access to the UT, and implement a delay time to mitigate rapid signaling to foreign HNBs in a dense HNB deployment. Accordingly, the subject disclosure provides for more efficient UT access in heterogeneous access type networks.

Description

201014397 VI. Description of the Invention: [Technical Field of the Invention] The following disclosure relates generally to wireless communications and, more particularly, to remote access by a management device in a restricted access point loop. According to the priority claim of 35 U.S.C. §119 - This application claims the application entitled "METHODS, on October 1, 2007

APPARATUS, AND SYSTEM FOR SUPPORTING ACCESS POINT BASE STATIONS WITHIN A WIRELESS WAN ❿ SYSTEM" priority to US Provisional Application No. 60/976,738, which is assigned to the assignee of the present application and explicitly </ RTI> </ RTI> <RTIgt; </ RTI> <RTIgt; </ RTI> <RTIgt; </ RTI> <RTIgt; </ RTI> <RTIgt; </ RTI> <RTIgt; </ RTI> <RTIgt; The patent application has the assignee number 080073 (QUAFP 1366 US), which is hereby incorporated by reference herein in its entirety in its entirety in its entirety in the the the the the the the the the the [Prior Art] - Wireless communication systems are widely deployed to provide various types of communication (e.g., voice, data, multimedia services, etc.) to multiple users. Pre-defined services allow users to access and utilize the various communication content on the service provider's network. As the demand for high-speed and multimedia data services grows rapidly, there are challenges in implementing efficient and robust communication systems with enhanced performance. 137601.doc 201014397 Traditional fixed line communication systems, such as digital subscriber line (DSL), cable lines, dial-up connections, or similar connections provided by Internet Service Providers (ISPs), are an alternative to wireless communications and sometimes Its competitive communication platform. However, in recent years, users have begun to use mobile communications instead of fixed line communications. Several advantages of mobile communication systems, such as user mobility, small relative size of user equipment (UE), and easy access to public switched telephone networks and the Internet, have made such systems very convenient and therefore Very popular. As users have begun to rely more on mobile systems for traditionally obtained communication services over fixed-line systems, the need for increased bandwidth, stable service, high voice quality and low price has increased in addition to current operations. In addition to the telephone network, a new type of small base station has also appeared. These small base stations are low power and can typically be communicated over fixed lines to connect with the operator's core network. In addition, such base stations can be distributed for personal/private use in homes, offices, apartments, private entertainment facilities, etc. to provide indoor/outdoor wireless coverage to mobile units. Such personal base stations are generally referred to as access point base stations, or as home Node B units (HNBs) or pico cells. The ultra-micro cell base station provides a new paradigm in mobile network connectivity that allows users to directly control mobile network access and access quality. SUMMARY OF THE INVENTION A simplified summary of one or more aspects is presented below in order to provide a basic understanding of the aspects. This summary is not an extensive overview of all intended aspects and is not intended to identify key or important elements of all aspects, and is not intended to depict any or all aspects of the 137601.doc 201014397. Its sole purpose is to present some of the concepts of the embodiments in the The present invention provides a wireless network that facilitates access by a user terminal (υτ) to a base station (BS) having a disparate access type. In some aspects, BS parameterization is provided to facilitate transitions between distinct types of network BSs. For example, parameters can be configured to increase or decrease UT search or handoff to a particular type of BS (such as restricted access (RA) home node B (HNB) or general access (GA) macros. The possibility of BS). In other aspects of the invention, a public land mobile network (PLMN) identifier (ID) is provided to the RA BS to distinguish between the BS and the GA macro BS. Therefore, the UT can identify whether the received wireless signal originates at an RA BS based on the PLMN ID. According to another aspect, an RA zone ID is established for the RA PLMN, and the UT can be associated with a particular home zone. If the UT roams into a home zone, it can search for and attempt to access the RA BS. When the UT is not in the home zone, it can ignore the RA BS, thereby reducing the signalling consumption in the non-home zone. When in the home zone, the UT can track down failed and successful access attempts, thereby reducing the likelihood of subsequent access failures and facilitating the identification of subsequent RA BSs that permit UT access. • According to another aspect, a method for providing mobile access in a wireless network is disclosed. The method can include obtaining a wireless signal including a network access request and allowing or denying the network access request. Additionally, the method can include transmitting a set of UT parameters that increase the likelihood that the UT will obtain and access the RA BS or reduce the likelihood that the UT will access the GA BS instead of accessing the RA BS. According to other aspects, a BS is provided. The BS may include: a transceiver 137601.doc 201014 397 'which obtains - contains - a wireless signal for network storage; and a registration module that allows or denies the network access request. In addition, the bs may include a selective access module that uses the transceiver to transmit a set of 1 parameters to increase the likelihood that the UT will obtain and access the RA BSi or decrease by one; possibility. According to one or more additional aspects, a device for providing mobile access in a wireless network is disclosed. The device can include means for obtaining a wireless signal including a network access request and for allowing or denying the The component of the network access request. In addition, the apparatus may include means for transmitting a set of 1;7 parameters which increase the likelihood that the UT will acquire and access the RA BS or reduce the likelihood that the UT will access the GABS. According to other aspects, a process is disclosed A device configured to provide mobile access in a wireless network. The processor can include a first module that obtains a wireless signal including a network access request, and a second module that allows or denies the network access request. Alternatively, the processor can include a third module 'which transmits a set of UT parameters, increasing the likelihood that the UT will acquire and access the RA BS or reduce the likelihood that υ will access the GABS. In one or more other aspects, a computer program product comprising a computer readable medium is provided. The computer readable medium can include: a first set of codes for causing a computer to obtain a wireless signal including a network access request; and a second set of codes 'to cause the computer to permit or deny the network Access request. Further, the computer readable medium can include a third set of codes for causing the computer to transmit a set of UT parameters that increase the likelihood that the UT will obtain and access the ra BS or reduce the likelihood that the UT will access the GABS. 137601.doc 201014397 In accordance with still another aspect of the present invention, a method of access-wireless network is disclosed. The method can include receiving a wireless signal transmitted by a wireless network, and obtaining a set of parameters that are configured to weight the use of a mail or GA BS to interface with the wireless network. Additionally, the method can include employing the set of parameters to effect communication with the network. In other aspects, a UT is provided that is configured to access a wireless network. The UT can include a transceiver that obtains a wireless signal transmitted by a wireless network. Additionally, the υτ can include a signal processor that obtains a set of parameters that are configured to weight the likelihood of employing the RA BS or GA BS to interface with the wireless network. In addition, the port can include an access module that employs the set of parameters to effect communication with the network. According to another aspect, an apparatus for accessing a wireless network is disclosed. The apparatus can include means for receiving a wireless signal transmitted by a wireless network 88 and means for obtaining a set of parameters configured to weight the RA BS or GA BS to interface with the wireless network The possibility of interfacing ❶ further 'the device may comprise means for employing the set of parameters to implement communication with the network. In addition to the foregoing, a processor is disclosed that is configured to access a wireless network. The processor can include: a first module that receives a wireless signal transmitted by a wireless network BS; And a second module that obtains a set of parameters 'the set of parameters configured to weight the possibility of using the RA BS or GA BS to interface with the wireless network, and further, the processor may include a second mode The group's use this set of parameters to implement communication with the network. In at least one other aspect, a computer program product comprising a computer readable medium 137601.doc 201014397 is provided. The computer readable medium can include: a first set of codes 'used to cause a computer to receive a wireless signal transmitted by a wireless network Bs; and a second set of codes for causing the computer to obtain a set of parameters, The group parameters are configured to weight the possibility of using the RA BS or GA BS to interface with the wireless network. In addition to the foregoing, the computer readable medium can also include a third set of codes for causing the computer to employ the set of parameters to effect communication with the network. The continuation of the present invention is described in the following detailed description and claims. The following description and the annexed drawings are set forth in the claims However, the four aspects are merely illustrative of a few of the various ways in which the principles of the various aspects can be utilized, and the described aspects are intended to include all such aspects and their equivalents. [Embodiment] Various aspects are described with reference to the drawings, wherein like reference numerals are used to refer to the like. In the following description, numerous specific details are set forth However, it will be apparent that this aspect can be practiced without such specific details. In other instances, well-known structures and devices are shown in block diagram form in order to facilitate describing one or more aspects. Additionally, various aspects of the invention are described below. It should be apparent that the teachings herein may be embodied in a variety of forms and that any particular structure and/or function disclosed herein is merely representative. Based on the teachings herein, those skilled in the art will appreciate that the aspects disclosed in 137601.doc 201014397 herein may be implemented independently of any other aspect, and that two of the aspects may be combined in various ways or Two or more aspects. For example, the device and/or method of practice may be implemented using any number of the aspects set forth herein. In addition, apparatus or methods of practice may be implemented using one or more of the aspects set forth herein or in other structures and/or functionality. As an example, many of the methods, devices, systems, and devices described herein are described in the context of implementing improved base station (Bs) access in a heterogeneous wireless access point environment. Those skilled in the art should appreciate that similar techniques can be applied to other communication environments. The introduction of a Home Node B (HNB) base station (BS) into the wireless access network enables significant flexibility and consumer control of personal access to such networks. As wireless resources continue to grow, and as terminal device processing and user interface capabilities become more complex, users can use mobile devices to perform functions previously only available on PC and fixed line communications. The use of small portable devices for high-quality voice communications, Internet access, multimedia access and playback, and entertainment has resulted in highly-accepted consumer products. However, because macrowired wireless networks are deployed for large-scale public use, indoor reception may often be weaker than outdoor reception (eg, due to buildings, insulators, terrain, etc., absorbing RF signals) Significant control over personal wireless connectivity often eliminates most or all indoor connectivity issues. Therefore, HNB can be extended even further in a poor environment for macro networks. There are significant advantages due to the increased complexity of hnb and the industry's huge network. For example, 137601.doc 201014397 HNB deployment is usually unplanned or semi-planned, which means The installation of these is not controlled by the network operator. Therefore, the operator implements the ideal placement of hnb relative to other such access points or relative to the macro BS, and the HNB is shaped relative to other access point cells. The ability to signal or even know the exact location of these cells is limited. In addition, in the case of consumers who are free to purchase and install HNB deployments, in densely populated areas The installation of such cells in the domain may be very dense, resulting in radio resource contention between the neighboring ^3 and the macro cell. In addition, the HNB is usually associated with the Closed Subscriber Group (CSG) and only members of the CSG. Providing network access; for example, access is not provided to the general cellular public user. Therefore, the HNB deployment in the macro network will have restricted access (rA) bs and general access (GA) BS. Integration Many legacy mobile terminals are not equipped to distinguish between GA BS and RA BS, and therefore can spend a lot of power searching and trying to access RA BSs that will end up with denial of service. In addition, legacy terminals and legacy wireless networking The standard requires the mobile terminal to scan the incoming wireless signal to identify the best signal. In the case where there are only a few neighbors 33 that can be distinguished by the terminal, this is usually a process that can be implemented 1. However, in dense HNB deployments, Dozens or hundreds of HNBs may be present nearby (eg 'in a large urban apartment building') (&gt; if a local HNB (the UT is included in the CSG) is located in the dense HNB deployment' Identify the local HNB collection In the case where the pilot and control channel of the home HNB is stationed in the HNB, the problem becomes that the problem is that the hNB signal is ignored and concentrated in the macro network. The present invention provides a solution for integration or heterogeneous deployment of RA BS and GA BS. 137601.doc • 11· 201014397 In order to solve the aforementioned problems, the aspect of the present invention provides for guiding τ search and accessing specific types. BS instead of other types of BS mechanisms. These mechanisms are designed to modify the legacy presets that cause the UT to search, camp on, and/or hand over to the cell with the strongest signal or lowest path loss. Since the RA BS only provides network access to the CSG, the strongest signal and/or lowest path loss is not entirely the best standard for selecting a network cell. Thus, the modified cell selection and search disclosed herein can incorporate a preference for the 83 type into a conventional preset. In addition, the disclosed subject matter can be used for single-frequency or multi-frequency wireless network deployment. According to some aspects, UT parameterization can be provided by a network such that a υτ is more likely to search for and access the RA BS than the GA BS. Or vice versa "In some of these aspects, the capabilities of the UT can be obtained at the network and the parameterization can be configured for the UT or a type 2 UT. For example, if the UT is an RA capable device (eg, having one HNB subscription and belonging to one of the one or more HNBs), the bias can be identified, accessed, camped on, and/or handed over to The parameters of the RA BS are provided to the U7. On the other hand, if the UT does not have the RA capability, the parameters for identifying the GA Bs, accessing the BS, etc. are provided instead. In other aspects of the invention, multi-frequency parameterization is also provided to weight favor or object to a type of BS UT preference. For example, in the case of HNBs and macrocells, using different frequencies or having at least one macro or only hnb frequencies, the network may establish a preference for one or another type of frequency, depending on UT capabilities (example The fact that β such preferences may make it more likely to be searched or camped on one type 68 rather than another. Thus, 137601.doc -12· 201014397 directs an RA capable UT to the HNB BS and/or HNB frequency to increase the likelihood of discovering the HNB associated with the UT. The RAT without RA capability can be directed to the macro network and/or the macro frequency to reduce or eliminate the signaling to the HNB, reduce the access denial from the unrelated HNB, and properly to the macro network and the HNB network. The road is load balanced. • Other aspects of the present invention provide for reduced signaling in the dense unplanned/semi-planned-deployment of HNBs. In this environment, a UT is typically included in a CSG of only one or a few HNBs (e.g., a home HNB), and many other φ HNBs exclude it. Thus, in the presence of many HNBs in a relatively small area, the UT may consume significant processing power and battery life to signal various excluded HNBs until a home HNB is found. As a specific example for explaining one of the foregoing, if a user is driving through a residential area containing a plurality of HNBs, the best signal received at the UT is constantly changing, thereby causing the UT to quickly search for a new cell and quickly try Hand over to the new community. The signal consumption and consumption of battery life in this situation can be enormous. ® To compensate for the above issues, an ultra-miniature public land mobile network (PLMN) identifier (ID) can be defined for the HNB BS. Each HNB can broadcast the pico PLMN ID with its pilot signal, along with the data identifying the HNB and other HNBs. If a UT is not in the area where it is expected to find an associated home HNB, then the pico PLMN ID and all signals carrying this ID may be ignored. Thus, in the event that the user is driving in a block that is not in the neighborhood of his home, the UT may ignore the HNB signal and/or frequency channel associated with the pico PLMN ID. The UT will therefore have a tendency to capture the macro BS 137601.doc -13- 201014397 road BS instead of RABS. However, if the ^^ is in the zone associated with the home HNB, the preference may be given to the BS broadcasting the pico PLMN ID and/or the frequency utilized by the BSs, as described above, rather than a macro network BS/frequency. Therefore, the UT will have a tendency to capture the RA BS instead of the GA macro BS. According to other aspects, if the UT requests network access from a BS and the access is denied (eg, 'when the BS has a CSG that does not include the υτ), the UT may revert to the macro BS The frequency and / or ignore the • pico PLMN ID in a penalty time. This can help reduce or eliminate the continued rejection of non-native RA BSs and the increased signaling overhead involved (e.g., when the user is driving through the dense deployment of the HNB). In addition to the foregoing, the UT may also record the cell ID of the HNB rejecting an access request (e.g., &apos;identified via the pico PLMN ID) to avoid subsequent signaling to the BS. Similarly, the BS can record the cell ID ' of the HNB providing access to the UT and give preference to the cell ID. By using these and similar technologies, the UT can utilize the HNB technology while mitigating the density of the heterogeneous access type BS. The adverse effects involved in unplanned deployments. The techniques described herein can be used for such things as code division multiple access (CDMA), time division multiple access (TDMA), frequency division multiple access (FDMA), and orthogonality. Crossover • Multiple Access (OFDMA), Single-Carrier Frequency Division Multiple Access (SC-FDMA), and other wireless communication systems in other systems. The term &quot;system and &quot;network&quot; is often used interchangeably. A CDMA system may implement a radio technology such as Universal Terrestrial Radio Access (UTRA), CDMA2000, etc. UTRA includes Wideband CDMA (W-CDM Winter) and CDMA Other variants. CDMA2000 covers 137601.doc • 14- 201014397 IS-2000, IS-95 and IS-856 standards. TDMA systems can implement radio technologies such as the Global System for Mobile Communications (GSM). OFDMA systems can be implemented such as Evolved UTRA ( E-UTRA), Ultra Mobile Broadband (UMB), IEEE 802.11 (Wi-Fi), IEEE 802.16 (WiMAX), IEEE 802.20, Flash-OFDM®, etc. UTRA and E-UTRA are general mobile telecommunications Part of the System (UMTS). Long Term Evolution (LTE) is an upcoming version of UMTS that uses E-UTRA, which uses OFDMA on the downlink and uses SC-FDMA on the uplink. UTRA, E-UTRA, UMTS, LTE And GSM is described in documents from an organization named &quot;3rd Generation Partnership Project (3GPP). CDMA2000 and UMB are described in documents from an organization named "3rd Generation Partnership Project 2&quot; (3GPP2). As used in the present invention, the terms &quot;components&quot;, &quot;system&quot;, &quot;module&quot; And similar persons are intended to refer to computer-related entities, which are hardware, software, software in execution, firmware, intermediates, microcode, and/or any combination thereof. For example, a module can be (but not Limited to processes, processors, objects, executables, threads, programs, devices, and/or computers executing on a processor. One or more modules may reside in a process and/or execution thread. And a module can be positioned on an electronic device and/or distributed between two or more electronic devices. Further, the modules can be executed from various computer readable media having various data structures stored thereon. The modules can communicate, for example, according to a signal by means of a local and/or remote process, the signal having one or more data packets (eg, from another signal in the regional system, the distributed system by means of the signal) Component interaction / or a component of a component that interacts with other systems, such as the Internet.) In addition, 137601.doc •15· 201014397 As will be appreciated by those skilled in the art, the components or modules of the systems described herein. It may be reconfigured and/or supplemented by additional components/modules/systems to facilitate the achievement of various aspects, objectives, advantages, etc., as described, and is not limited to the precise configuration stated in a given schema. In addition, this article describes various aspects in combination with user terminals (υτ). υτ can also be called system, subscriber unit, subscriber station, mobile station, mobile phone, mobile communication device, mobile device, remote station, remote terminal. Machine, access terminal (AT), user agent (UA), user device or user equipment (UE) or the like. The subscriber station can be a cellular telephone, a cordless telephone, a session initiation protocol (SIP) a telephone, a wireless area loop (WLL) station, a personal digital assistant (PDA), a palm-connected device with wireless connectivity, or a similar mechanism that connects to a wireless data modem or facilitates wireless communication with a processing device. He processes the device. In one or more exemplary embodiments, the functions described may be implemented in hardware, software, firmware, intermediates, microcode, or any suitable combination thereof. If implemented in software, such functions may serve as The one or more instructions or code are stored on or transmitted over a computer readable medium. The computer readable medium includes computer readable hardware including computer storage media and hardware communication media, and the communication media includes Any software, intermediate, firmware, microcode, and/or hardware media that transfers a computer program from one place to another. As used herein, a computer storage medium can be any physical medium that can be accessed by a computer. By way of example and not limitation, the storage medium may include RAM, ROM, EEPROM, CD_R〇M or other disk storage disk storage or other magnetic storage device, smart card and flash memory device! 37601.doc 201014397 (eg M-disc..) or any other suitable medium that can be used to load or store program code in the form of an instruction or data structure and accessible by a computer.The hardware communication medium may include any suitable device or data connection that facilitates the transfer of computer programs from one entity to another at least in part using t, mechanical, and/or electromechanical. In general, data connections '(4) are collectively referred to as computer readable media. For example, if you use coaxial cable, 'fiber cable, twisted pair cable, digital subscriber line (DSL), communication bus structure, Ethernet or wireless technologies such as infrared, radio and microwave, you can Coaxial cable, fiber optic cable, twisted pair, DSL, or wireless technologies such as infrared, radio, and microwave, included in the definition of media, and with such media, or other remote source transmission programs, soft cameras, or other materials. Any suitable hardware components are included as defined herein in the definition of hardware communication media, including compact discs (CDs), laser discs, compact discs, digital versatile discs (DVD), soft magnetics. Discs and Blu-ray discs, in which a disc typically reproduces material magnetically, while a disc optically reproduces data by laser. Combinations of the above should also be included in the computer readable media. For hardware implementations, various illustrative logic, logic blocks, modules, and circuits of processing units described in connection with the aspects disclosed herein can be implemented or implemented in the following: one or more special application complexes Circuit (ASIC), digital k processor (DSP), digital signal processing device (dspd), programmable logic device (PLD), field programmable gate array (FPGA), discrete gate or transistor logic, discrete hard Ship components, general purpose processors, controllers, microcontrollers, microprocessors, 137601.doc -17- 201014397 other electronic units or combinations thereof designed to perform the functions described herein. A general purpose processor may be a microprocessor, but in the alternative, the processor may be any conventional processor, controller, microcontroller, or state machine. The processor can also be implemented as a combination of computing devices, such as a combination of a DSP and a microprocessor, a plurality of microprocessors, one or more microprocessors in conjunction with a Dsp core, or any other suitable configuration. Additionally, at least one processor can comprise one or more modules operable to perform one or more of the steps and/or actions described herein. In addition, the various aspects or features described herein can be implemented as a method, apparatus, or article of manufacture using standard stylization and/or engineering techniques. Furthermore, the steps and/or actions of a method or algorithm described in connection with the aspects disclosed herein may be embodied in a hardware, in a software module executed by a processor, or in a combination of the two. In addition, in some aspects, a method or algorithm steps and/or actions may reside on a device readable medium, a machine readable medium, and/or any combination or combination of code and/or instructions. / or computer readable media, such media can be incorporated into a computer program product. The term "article of manufacture" as used herein is intended to encompass a computer program accessible from any computer readable device or medium. Additionally, the word "exemplary" is used herein to mean serving as an example, instance, or illustration. Any aspect or design described herein as "exemplary" is not necessarily construed as being preferred or advantageous over other aspects or designs. In fact, the use of the word "exemplary" is intended to present a concept in a specific manner. As used in this application and the scope of the accompanying claims, the term &quot; or &quot; is intended to include the term &quot; or &quot;Non-exclusive&quot; or ie, unless otherwise indicated or clear from the context 'otherwise' X adopts A or B" to mean any of the natural inclusion arrangements 137601.doc -18- 201014397: ie, If X uses A; X uses B; or X uses both A and B, then the case in the month's example satisfies &quot;X adopts A or B." Otherwise unless otherwise indicated or not from the context It is clear that the word "single" is used in the singular form, and the term "a" used in the scope of the application and the accompanying patent application is understood to mean "one or more". As used herein, the term "inference" generally refers to the process of capturing or inferring the state of the system, the environment, and/or the state of the user by capturing a set of observations via events and/or materials. Inferring the probability distribution that can be used to identify a particular clearing or action, or to generate a state. The inference can be probabilistic, that is, based on the consideration of data and events, the machine of interest is calculated = the inference can also refer to Substituting techniques for constructing a relatively high-level event from a set of events and/or data. This inference results in the construction of a new event or action from a set of observed events and/or stored event data, regardless of the temporal proximity of the event. Whether it is closely related, and regardless of whether the event and data are from one or several events and sources of information. _ Referring to the drawings, Figure 1 illustrates an exemplary wireless communication system that is configured to support multiple users, various The disclosed embodiments and aspects can be implemented in the wireless communication system 100. As shown in Figure i, the system 1 is a plurality of cells, such as macro cells l〇2a, 102b, 102c, 1〇2 d, i〇2e, l〇2f, l〇2g (or, macro cell 1〇2&amp; to 1〇2§) provide communication such that each cell is associated with a corresponding access point (Ap) 1〇4a, L〇4b, 1〇4c, l〇4d, 104e, 104f, 104g (or ' Ap(7)饨 to (7)#) services. Each cell 102a to l〇2g can be further divided into one or more sectors ◊ various 106τ 106a , 106b, 106c, 106d, l〇6e, l〇6f, i〇6g, i〇6h, 137601.doc • 19- 201014397 106i, 106j, 106k (or UT l〇6a to 106k) are scattered throughout the system 100. Each AT l〇6a to l〇6k can communicate with one or more ap l〇4a to 104g on the forward link (FL) and/or reverse link (RL) at a given time. 'This depends on whether the AT (106a to l〇6k) is active or whether it is in soft handover (for example). The wireless communication system 100 can provide services on a large geographical area, for example, giant The set cells 102a through 102g may cover several nearby neighborhoods. Figure 2 depicts an exemplary communication system 200 to enable deployment of access points bs (e.g., HNBs) within a network environment. The system 200 includes multiple Access point BS Each of them, including HNB 210, is installed in a corresponding small-scale network environment. Examples of small-scale network environments may include user residences, work locations, indoor/outdoor facilities 230, etc. HNB 210 may be grouped. The UT 220 is associated with the service (e.g., included in the CSG associated with the HNB 210), or externally or by the visitor υτ 220 (e.g., not configured in the HNB 210). Each 1^8210 is further coupled to the Internet via a 〇81 router (not shown) or cable modem, power line broadband connection, satellite network splicing connection or similar broadband internet connection (not shown). 240 and the operator core network 250. In order to implement wireless services via the HNB 210, the owner of the HNB 210 subscribes to mobile services provided by the mobile operator core network 25, such as mobile services. Moreover, UE 220 may be able to operate in a macrocelled environment and/or in a residential small-scale network environment using the various techniques described herein. Thus, at least in some of the disclosed aspects, Hnb 210 can be backward compatible with any suitable existing UE 220. In addition, in addition to the macro 137601.doc -20- 201014397 regional mobile network 250, the UE 220 is also served by a predetermined number of HNBs 210, specifically, resident in a corresponding user residence, work location, or indoor/ The HNB 210 within the outdoor facility 230 is serviced and cannot be in a soft handoff state with the macro network 250. It should be understood that although the aspects described herein use 3GPP terminology, it should be understood that the aspects can also be applied to 3GPP technologies (versions 99 [Rel99], Rel5, Rel5, Rel7) and 3GPP2 technologies (lxRTT, lxEV-DO). RelO, RevA, RevB) and other known and related technologies. • Figure 3 illustrates a block diagram of an example system 300 that facilitates searching or handing over preferences based on BS type or category, in accordance with aspects of the present invention. This preference may depend on the capabilities of the UT 304, the location of the UT 304, the load on the network, or similar system implementation factors. It should be appreciated that system 300 can include multiple wireless access points having disparate access types. In this environment, facilitating UT preferences for a given type of access point can result in efficient load balancing, reduced signaling consumption (eg, especially in dense unplanned deployments), and retrieval of the UT associated with the UT. The possibility of a home BS increases or the ability to remain connected to the home BS increases once the BS is captured. System 300 includes a BS 302 that can be in a network of neighboring BSs (not depicted) of disparate types or classes. Examples of different types/categories of base stations include GA BS or RA BS, fully reused or partially reused BS, high power (e.g., macro cell) or low power (e.g., pico cell, pico cell) BS or the like , or a combination thereof. The BS 302 includes a wireless transceiver 306 for transmitting data in a geographic area served by the BS 302. The transmitted data includes broadcast data relating to many or 137601.doc -21 · 201014397 remote terminal devices (304) located in the geographic area, unicast data transmitted to a specific UT 304 or transmission data. A selective channel of a subset of devices. Broadcast data typically includes captured and synchronized pilot signals, including

Information for identifying and decoding data transmitted by BS 3〇2 (for example, ID of BS 302, pLMN(1) associated with BS 3〇2, time frame and subslot synchronization timing, and interference for write channel Code, etc., and control channel information for configuring the variable parameters of υτ 304 to communicate with BS 3〇2. Unicast

It is usually used for the traffic and control channel information of the remote terminal. Selective channels may include paging channels and deliverable information to selected. Ding's other control channels.

As a specific example for explaining preference parameterization, it is assumed that Bs 3〇2 can be a GA macro BS or an RA BS, such as an HNB. The BS 302 includes a selective access module 3〇8 that transmits a parameterization scheme configured to direct a 〇τ 3〇4 search and/or capture a BS of a particular type or class. Thus, by way of example, this parameterization may increase the likelihood that the UT 304 will recognize the RA BS instead of the GA BS, or vice versa. In some of these aspects, the parameterization provides a relative priority hierarchy for BS 302 and neighboring BSs (not shown) depending on the type of BS. Specifically, if the BS 302 is an RA BS, the priority hierarchy can provide the first priority to the BS 302, and if the BS 302 is a GA BS, provide a second priority different from the first priority. Alternatively or in addition to the foregoing, the priority hierarchy may assign relative priorities to different frequency channels employed by the network BS. The frequency used by the high priority BS can also be given a relatively high priority, and the frequency exclusively used by the high priority BS can be given the highest priority. Similarly, the frequency dominated by the low priority bS 137601.doc -22-201014397 can be given a relatively low priority, and the frequency dedicated to the low priority BS can be given the lowest priority. Priority may depend on the RA capabilities of the UT 304, as appropriate. For example, if *υτ 3〇4 does not have a subscription, the priority hierarchy can provide the GA with a higher priority than the ra BS to increase the UT 3〇4 to be camped on and/or handed over to ga. The possibility of bs instead of RA BS. An example of such a priority hierarchy may include a hierarchical cell structure (hcS) employed in a W-CDMA network. The term &quot;hierarchical cell structure&quot;, while used as a specific parameter in a CDMA environment, is used in a generic sense as described herein and in the accompanying claims, and refers to a cell/sector for a BS and/or network. Any suitable priority leveling may include a priority level configuration of the frequency channel employed thereby. The HCS may provide a common priority level configuration to the BS and the frequency channel' or may provide separate priority levels to the BS and the channel.

In addition to the foregoing, &apos;parameterization can be configured to modify the likelihood that the UT 304 will search for neighboring BSs depending on the type of BS (302) in which the UT 304 or UT 304 is camped. Because the signal strength and/or quality is a variable reality, it varies with the location of the UT 304, the BS load, the interference from the BS and/or υτ (not depicted) in the neighboring cell, topological interference, etc., so a specific BS 302 may not provide the best signal at a particular point in time. The xjt 304 can be configured to search for and analyze the signals of neighboring BSs (302) to identify the best available signal. The search can be initiated periodically in some aspects to detect periodic changes in the relative signal strength/quality of neighboring BSs and identify the BS with the best signal characteristics. In other aspects, the search may be initiated if the signal currently hosted by the UT 304 or service 137601.doc -23- 201014397 UT 304 falls below a threshold. A neighboring BS with a better signal can be added to a valid handover set, camped on the cell, or handed over to the cell. For 没有τ without RA-capable services

304 can maintain this program as a preset. However, the RA capable UT 304 can achieve significant benefits when served by a home, and thus can be kept on the home, even if a neighboring cell provides a better signal. Therefore, it may be helpful to modify the default rules for searching for and extracting the best signal, especially in a network that is capable or for a capable UT (304). To implement the modified BS search, a search parameter is established that provides a minimum signal strength and/or quality threshold for a service/resident signal. If the signal falls below the threshold, UT 3〇4 searches for the neighbor BS with the better signal. If the signal remains above the threshold, then υτ 3〇4 does not search for neighboring BSs (or, for example, only BSs having the same or higher priority). To implement a preference for a particular type of BS, the threshold can be set relatively low for a preference type and/or set relatively high for a non-preferred 38 type. Therefore, the υτ 3〇4 is more likely to search for a stronger signal from the neighboring bS when the non-preferred BS is served by the non-preferred BS and is less likely to be camped on the preferred BS/served by the preferred bs Search for neighboring BSs. In some aspects, the search parameters may be commensurate with the hcs priority as discussed above. By coupling the HCS and the search parameters, if the strength/quality of the received signal is above the search parameter threshold, the UT 304 can be configured to only search for the same or higher priority BS (302). However, if the strength/quality falls below the search parameter threshold, then the UT 304 can then search for a winter neighbor BS with a lower hierarchical priority level 137601.doc -24- 201014397. In the extra aspect, the modified B S search can be implemented based on the channel frequency of the multi-frequency wireless system. Thus, for example, inter-frequency and/or intra-frequency search parameters can be established with a threshold below which the frequency of the current signal (eg, service signal, camping signal) is compared to the current signal (eg, service signal, camping signal) The UT 304 searches for BSs on different frequencies and/or other BSs on the same frequency, respectively. In order to implement a preference for a BS type (eg, RA BS), a low relative inter-frequency/intra-frequency search parameter is provided to a preferred type of BS, and a high relative inter-frequency/intra-frequency search is provided to a non-preference type of BS. parameter. Thus, when served by the preferred BS (302), the UT 304 tends not to search for other frequencies and/or not to search for other Bs within the frequency. Similarly, when served by a non-preferred BS, UT 304 is more likely to search for other frequencies (e.g., to identify frequencies that include preferred BS 302) and/or to search for other BSs on the current frequency. Alternatively or in addition to the foregoing, the selective access module 3〇8 can be configured to control parameters that are handed over from one BS (302) to the other. As with the search parameters, the handover parameters can be weighted to increase the likelihood of handing over to a preferred BS (3〇2) and reduce the likelihood of handing over to a non-preferred BSi. In addition, the preference/non-preference BS may be defined in accordance with the type or class of the BS (e.g., RA, GA). In addition, the definition of preference/non-preference may depend on the ability of Kenting. As an example, if the UE 304 is configured for the first type of BS instead of the first type, the handover (and Bs/frequency priority hierarchy and search) parameters of the preferred first type of BS may be forwarded. To the UE 3〇4. Likewise, if the UE 304 is configured for a second type 38 or a second type of preference 13760I.doc -25-201014397 service, the parameters of the second type of BS may be forwarded to the UE 304. In other aspects, if the UE 304 has no particular preference, the preset parameters for the macro network access can be forwarded to the UE 304. It will be appreciated that UT 304 capabilities and/or preferences may be obtained in a variety of suitable manners. In one example, the capabilities/preferences are freely available to a user location profile by a home location register (HLR, not depicted). In other examples, the capabilities/preferrions may be stored in memory at UT 304 and forwarded to BS 302. In the latter case, the selective access module group 308 can broadcast preset parameters via the transceiver 306 (which optionally prefer one or another type of BS, as described above), and once the UT 304 is obtained at the BS 302. The capabilities/preferences are then transmitted (306) to the group-specific parameters to the UT 304. The parameterization received at UT 304 can be used in conjunction with BS and/or wireless channel search, retrieval or handover procedures, as described above. Thus, UT 304 can camp on signals transmitted by BS 302 or attempt to access a mobile network via BS 302. In order to access the mobile network, the UT 304 requests network access and submits information identifying the UT 304 and the user account associated with the UT 304. Depending on the circumstances, the CSG identifier of UT 304 may also be included with the network access request (e.g., if UT 304 has an HNB subscription) to facilitate access to the home HNB associated with UT 304. In other aspects, the CSG identifier can be included in

From the reservation profile information obtained by an Internet operator's HLR. The registration module 3 10 can use the subscription and/or CSG identifier information to determine whether to allow or deny the network access request. If the BS 302 is a GA BS, the decision to allow or deny may be based on whether the UT 304 has made a reservation to the operator. If BS 137601.doc -26-201014397 302 is an RA BS, then the determination may be based on whether the UT 304 has subscribed to an industry and is included in the CSG associated with BS 302. If the registration module 310 approves the access request, the UT 304 can initiate and/or receive communication services, including voice or material calls, internet access, or the like. 4 illustrates a block circle transmitted by a network BS 402 to an instance parameterized record 406 of an UT 404. The parameterized record 406 can be broadcast by the BS 402 to the UT 404 within one of the sectors of the wireless communication network served by the BS 402. According to some aspects of the present invention, the parameterized record 406 can provide a threshold parameter, the weighted UT 404 is searched, retrieved, and/or handed over to a particular type of network or a particular class of honey BS. (402) The possibility. Thus &apos;parametric record 406 can be used to direct ϋΤ (404) to one or another type of BS in a network containing disparate access type BSs (402), such as RA BSs and GA macro BSs. The selection of the preferred and/or non-preferred BS (402) may be based on sector loading, UT capabilities, inter-sector interference, and the like.

The parameterized record 406 can include an HCS parameter 408 that establishes the relative priority of the BS 402 and neighboring BSs (not depicted) in a wireless access network. The HCS ♦ parameter 408 can be coupled with a cell search parameter 412 to modify the preset search parameters of the UT 404. Thus, for example, the HCS parameters 408 can have different access types, different reuse types (eg, full reuse, partial reuse, etc.), different transmission power (eg, 50 watt macrocell, 25 watts) Microcell, 5 watt picocell, 1 watt microcell or some other suitable combination of network cell size and transmission power), different access technologies (eg, wireless fidelity [WiFi], microwave access global interworking [WiMAX] ], licensed cellular RF) or the like or a combination thereof BS (402) provides relative priority 137601.doc -27- 201014397 (eg 'contains quantitative priority such as numerical scale or such as high, medium, The qualitative priority cell search parameter 412 of the low or other relative indicator may establish one or more minimum thresholds for various types of BSs (402) below which the UT 404 may search for the first The group BS type, and above the (equal) threshold, the UT 404 may search for a second set of bS types. In some aspects, the (equal) group of BS types may be established by the HCS priority parameter 408. An example, HCS parameter 408 Establish three priority 'for low priority of any suitable type of GA BS, for partial reuse of BS (for example, micro or pico-cells using only one part of the channel bandwidth) which is comparable to all channel bandwidths Reusing the BS is more efficient) among the priority 'and the high priority for the HNB. The cell search parameter 412 can then establish a high and minimum threshold for the low priority BS (e.g., such as the GA macro cell β§) a value, a minimum threshold for the medium priority BS, and a low minimum threshold for the high priority BS. In this case, if υτ 404 is served by an HNB or camped on the HNB, as long as the HNB If the signal satisfies the low minimum threshold, the UT 404 will not search for other BSs, or will only search for other high priority BSs as appropriate. However, if the UT 404 is re-used by the medium priority part, as long as the part is again If the signal of bs satisfies the minimum threshold, the UT 404 will only search for the high priority BS, or search for other medium priority if the service BS has a better signal than the partial reuse BS in the service. Priority BS, then the signal strength satisfies the high minimum In the case of a limit, the UT 404 will search for the high or medium priority bs and, if the signal strength does not satisfy the high minimum threshold, search for any other suitable BS. The HCS parameters 408 and the cell in the WCDMA network. 137601.doc of the search parameter 412 • 28· 201014397 The specific examples are the hcs_prio parameter and the SsearchHCS parameter respectively. However, it should be understood that the present invention is not limited to the WCDMA network and parameters. The fact is that it is expected to have similar BS priority and search parameters. Other suitable wireless network systems (such as 3GPP LTE, UMB, WiMAX, UMTS, etc.) are part of the present invention. • The parameterized record 406 can also include a UE access type 410 parameter that includes some of the capabilities of the UT 404. Such capabilities may be obtained from the UT 404 or obtained from a network operator's HLR or from other suitable network data sources. In addition, the UE access type 410 can be used as a selective parameterization flag that selects a plurality of sets of parameters 408, 412, 414, 416, 418 configured for various UT capabilities and included in the parameterized record 406. One of the groups. Therefore, to continue the foregoing example, if the UE access type for the UT 404 is only a GA macro network, then a set of different HCS parameters 408 and cell search parameters 412 can be provided to the UT 404 and/or by the UT. 404 selection, instead of those listed in the above examples. For example, the HCS parameter 408 can give high priority to the GA macro BS and give low priority to the RA BS. In addition, the cell search parameter 412 can establish a high minimum threshold for the RA BSs that increases the likelihood that the UT 404 ignores such BSs or searches for other BSs when served by the RA BS and establishes for the GAs The low minimum threshold of the BS. It should be understood that there are other suitable priority and search parameter configurations that are related to different UT capabilities. For example, a set of different parameters can be established for the multi-mode WiFi/cellular UT (404), which is a WiFi access point, a cellular access point, or two compared to other access point types (eg, WiMAX). Establish a priority. In addition to the foregoing parameters, parameterized record 406 can further include a frequency 137601.doc -29-201014397 rate search parameter 414, action selection parameter 41 416, and a neighbor cell parameter 418. The foregoing parameters in the WCDMA case may include one

SlNTERSEARCH parameter (for example, for different available frequencies in a _, 々a, % network)

Inter-channel search), S丨NTRASEAReH parameters (for example, for searching in the -frequency channel) and QhyStlAQ0ffsetls, N (for example, for determining whether to hand over to another BS or adding another BS to a valid handover set) ). In a similar form as described above, the 'frequency search parameter 414, the mobile cell selection parameter 416, and the neighbor cell selection parameter 418 can be established with different minimum thresholds for each -hcs priority type. Additionally, a number of sets of preference and non-preference parameters 414, 4i6, 418 may be provided in accordance with the sacrificial type 410. Thus, for example, if UT 404 is RA capable, parameters 414, 416, 418 can be established for low minimum thresholds of RA BSs (such as HNBs) and for use in other types of BSs and/or High minimum threshold. In this case, the UT 404 is more likely to search and hand over to and within the frequency channel to the RA BS, and is more likely to remain stationed in the RA Bs/maintained by the RA BS service. Figure 5 illustrates the UT-specific information. The network BS provides a block diagram of an example system 500 that is selectively parameterized. As described herein, the υτ information can be used to configure different parameterizations depending on the capabilities of the UT or to select between parameter sets for different υτ pre-configurations. Therefore, the system 5 can provide backward compatibility with the old version υτ (for example, 'megabit UT only') and dual mode, multi-mode, RA capability, etc. in the network including the disparate access type bs. Dedicated service. Therefore, the system 500 can alleviate the wasted or redundant signaling of a BS that cannot or cannot be configured for access, and can also access various I37601.doc -30· 201014397 points in the network. Load balancing υτ. The result of this configuration can result in improved crewing of preferred access points (e.g., home ΗΝΒ, WiFi routers), reduced UT processing, and improved battery life. System 500 includes a BS 502, which can be any suitable BS that can interface with a mobile carrier's core network 510. Thus, BS 502 can include a GA BS, a WiMAX access point, coupled to the core network 510 via the Internet (not depicted, but visible in FIG. 2, at 210, 240, 250). One of the HNB or WiFi access points (eg, 3GPP core network), or its Φ-like. BS 502 typically broadcasts network information identifying the type of network (510) coupled to BS 502 (e.g., identifies the PLMN ID of the network 510) and distinguishes BS 502 from other network BSs (not depicted). BS information. In some aspects, the network information may include a dedicated PLMN ID reserved for a particular type of network. For example, the PLMN ID may be reserved for the BS 502 and identify the BS 502 as a HNB for a picocell network, a WiFi access point for a WiFi network, a WiMAX access point for a WiMAX network, or capable of interfacing to a core Other suitable nodes of the network of access points of network 510. Stomach After obtaining a wireless signal from a UT (not depicted), BS 502 can analyze the signal to determine if a dedicated PLMN ID associated with BS 502 is included in the signal. If so, BS 502 can assume that the UT is attempting to access the network as a dedicated .UT (e.g., an RA capable UT). The BS 502 may attempt to authorize the UT to determine whether to grant this special access. Thus, for example, if BS 502 is an HNB, the CSG of BS 502 can be referenced to determine if the UT is included in the CSG. If so, the UT can be provided with full access to the BS 502 and the core network 510. Otherwise, no limited access is provided or no access is provided to 137601.doc • 31 - 201014397. In addition to the dedicated PLMN ID information, the BS 502 can extract identification information (e.g., mobile user identity [MSI], international mobile subscriber identity [IMSI], etc.) associated with the UT. The data query module 504 can use the UT identification information and request a user profile from a local network registration 506. In a cellular scenario, the local network registration 506 may include a Global System for Mobile Communications (GSM) or UMTS network. The Mobile Switching Center (MSC)/Visitor Location Registration (VLR), in GSM, CDMA or WCDMA networks The service in the road is a general packet radio system (GPRS) Support Node (SGSN), or the like. For other access point networks, such as HNB, WiFi or WiMAX networks, the local network registration may contain network devices similar to MSC/VLR or SGSN, or may only contain information for storing and managing data. The library and the network interface and processing card authorized to access the core network of the provider and obtain user information. After obtaining the user profile request from the data query module 504, the local network registration 506 can submit the UT identification information to the core network 508 of the provider. In response, the user's native registration 508 (e.g., HLR) can provide the user profile m stomach 512 to the local network registration 506. The local network registration may retrieve the user profile from the user profile 512 and forward the data to the data query module 504 in response to the query. The user profile can be provided to an analysis module 5 14, which parses the data to identify and determine whether the UT is allowed to access, what type of access is allowed, what type of service can be supplied to the UT, etc. User information. This information may include the type of service plan, the user information of the UT, the PLMN ID of the service provider of the UT, the appropriate dedicated PLMN ID associated with the UT, 137601.doc -32- 201014397 the access capability of the UT, UT voice and / or data service capabilities, the UT's multimedia capabilities. If the user information indicates that the UT should be able to access the BS 502, the registration module 516 can approve access and transmit information suitable for communicating with the BS 502 (eg, including scrambling code, traffic channel configuration, and other suitable communications). parameter). • According to some aspects of the invention, the user profile information may include a native PLMNg associated with the UT. In at least one aspect, the home zone identifies a particular geographic area or network area (e.g., a particular macro cell or a group of macro cells) in which the UT's home HNB resides (especially Municipalities, cities, counties, towns, etc. or the like). Thus, when the UT is located within the native PLMN zone, the UT can expect to find a home HNB associated with the UT. In the event that the UT is not located within the native PLMN zone, the native HNB will not be expected. In order to determine if the UT is located within the designated home PLMN zone, the BS 502 can compare the location information of the home PLMN zone with the BS 502. If it is determined that the UT is located in the local PLMN zone, then it will be transmitted to the UT with the PLMN ID associated with the HNB BS. According to a specific aspect, the dedicated

The PLMN ID lists the equivalent PLMN ID as the network of the UT's provider. Because of this, the UT can then search, hand over, and camp on the dedicated PLMN.

The HNB of the ID, etc., is like the macro BS associated with the PLMN ID of the operator. Therefore, the UT can treat the PLMN ID as an equivalent of the PLMN ID of the operator. In one or more other aspects, if the UT is determined to be within a native PLMN zone, the BS 502 can further transmit a parameterized group 137601.doc-33-201014397 that establishes the HNB as a preferred BS, as described herein. Therefore, UT can not only regard HNB as equivalent to the macro network in the local PLMN area, but UT can be more likely to search, hand over and remain stationed in HNB/served by HNB. The possibility of HNB will increase. On the other hand, if it is determined that the UT is not located within the home PLMN zone, the dedicated PLMN ID is not given to the UT, and • only the provider PLMN ID associated with the UT is provided. Thus, the UT can ignore the HNB that broadcasts the dedicated PLMN ID because it can assume that these HNBs are not the UT's home HNB, and therefore will not provide full access or any access to the UT. Thus, system 500 can reduce or eliminate signaling to HNBs located in zones other than the home PLMN zone, and also increase the likelihood that the UT will find a home HNB in the borrowed PLMN zone. It should be understood that the native PLMN zone, although described above in the singular, may include more than one geographic or network area. Thus, for example, if the UT is included in the CSG of two HNBs located in a separate dedicated PLMN ID zone (one zone is at the user's home and the other zone is at the subscriber's office), then the home PLMN zone can The two dedicated areas are included, or the dedicated area can be defined to include two or more geographic areas or network coverage areas (eg, see 圊 6 below). Therefore, the PLMN area of the home can be a flexible identifier adapted for individual users. • Figure 6 illustrates a block diagram of an example network environment 600. Network environment 600 includes a number of network areas 608A, 608B, 608C, 608D (608A through 608D). A network area may be defined by a geographic area (e.g., a residential area, a municipality, a town, a county, etc.) or a network area (such as a Location Area Identifier (LAI) or a Routing Area Identifier (RAI)). Wireless communication services may also be provided to network areas 608A through 608D via a mobile operator's ground access point 602 (eg, 137601.doc • 34. 201014397, such as a 'base station). The network area, LAI, RAI, etc. may be defined by the mobile communication industry as part of the macro network coverage (602). As depicted, the network environment 600 includes at least four network areas 608A through 608D. The zones 608A through 608D are depicted in terms of their access relationship with the UT 604. Accordingly, the zones 608A through 608D include a first home PLMN zone - 608A, a first foreign PLMN zone 608B, a second foreign PLMN zone 608C, and a second home PLMN zone 608D. The home PLMN zone 608A, #608D includes at least one home HNB 606A, 606B associated with the UT 604. The home HNBs 606A, 606B include a CSG that includes information identifying a group of UTs (604) that can access the home HNBs 606A, 606B. Only limited network access/communication services are provided to UTs not included in the CSG, or no network access/communication services are provided. Similarly, all access/communication services provided by the HNBs 606A, 606B are provided to the UTs included in the CSG. As the UT 604 travels around the network environment 600, communication services are available from the Macro Network ® Access Point 602. However, the UT 604 can obtain priority services from a home HNB 606A, 606B (e.g., increased bandwidth, increased data rate, higher quality of service, reduced rate) compared to the macro network access point 602. In addition, by using the home HNB 606A, 606B, the macro network load is reduced. Therefore, it is beneficial for the UT 604 to obtain access rights from the home HNB when possible. Under the old network parameters, the UT 604 can It is interfaced with the home HNB BS 606A, 606B in a manner substantially similar to the macro BS 602. Therefore, the UT 604 can search for the strongest signal, and 137601.doc -35· 201014397 is stationed in any BS that provides the strongest/best quality signal ( 602, 606A, 606B) / request access thereto. When located outside of the PLMN areas 608A to 608D, the macro network may provide the best signal and will typically be selected by the UT 604. However, if the UT 604 is located Within one of the PLMN zones 608A-608D containing one or more HNBs (606A, 606B), the neighboring HNBs can have much better signal characteristics than the remote macro BS 602. Therefore, the UT 604 will be more likely Search, camp on these HNBs and request access to them. The deployment of the HNB can typically contain many more foreign HNBs than the native HNB (eg, where UT 604 is not included in the CSG), and thus the UT 604 can experience many access denials in attempting to access the strongest neighbor signals. This result can result in significant processing overhead and reduced battery life for UT 604. To alleviate the aforementioned problems, a dedicated PLMN ID is assigned to HNBs 606A, 606B of network environment 600. The dedicated PLMN ID can be unique among the PLMN IDs of the practitioners And, therefore, different from the PLMN ID of the macro network 602. Additionally, the HNB zone may be defined, which optionally matches the zone 608A to 608D of the network of the operator (eg, LAI zone, RAI zone, etc.). After an HNB radio subscription service, the UT 604 is associated with one or more native PLMN zones 606A, 606D. In general, when the UT 604 is located within a foreign PLMN zone • 606B, 606C, the UT 604 can ignore the inclusion of the dedicated PLMN ID. The signal can therefore alleviate the over-signal associated with attempting to access a strong signal from a neighboring foreign HNB. However, when the UT 604 is located within the native PLMN zone 606A, 606D, the network 600 can transmit the dedicated PLMN ID as PLMN The equivalent of the ID. Therefore, within the home PLMN areas 606A, 606D, the UT 604 can search for and request access to the HNBs 606A, 606B and the macro network 137601.doc -36-201014397 602, as described herein. The network may further provide parameters configured to increase the likelihood that the UT 604 will find and access the HNB on the macro network. Thus, the average time that the UT 604 needs to discover the home HNBs 606A, 606D rather than the foreign HNBs located in the home PLMN zones 606A, 606D can be reduced. In at least some aspects of the present invention, the UT 604 can be configured to improve detection of the home HNBs 606A, 606B within the native PlmN zones 608A, 608D in addition to the parameterizations described herein. In one example, UT 604 can record the ID of the HNB that denied network access to the UT 604 and include the IDs in a restricted list or blacklist. By &quot;remember&quot; which HNBs are restricted, the UT 604 can avoid signaling the HNB ID on the restricted list&apos; to reduce signaling and conserve battery power. In addition to the foregoing, the UT 604 can store the HNB IDs of the home HNBs 606A, 606B that are permitted to be accessed by the UT 604. The home HNB IDs may be included in the preference list&apos; and the signals including the home HNB IDs may be given priority over other signals. Thus, the UT 604 can camp on or request access to the home HNBs 606A, 606B and ignore signals from other BSs (e.g., as long as the signal from the home HNB is ultimately above a low relative threshold, as described herein). Figure 7 depicts a block diagram of an example system 7A in accordance with an aspect of the present invention, the system 700 including a BS 702 and one or more UTs 704 (e.g., mobile devices). The base station 702 can be configured to provide parameterization for weighting the search and/or access priority of the UT 704 in accordance with the bs type, as described herein. This parameterization may increase the likelihood that UT 704 will discover/access a type of bs 137601.doc -37- 201014397 or reduce the likelihood that UT 704 will discover/access a second type of BS. In some aspects, the parameters provided may be based on the capabilities of the UT 704. BS 702 (eg, an access point...) can include a receiver 710 that receives signals or wireless (OTA) messages from one or more UTs 704 via one or more receive antennas 706; Transmitter 728 transmits the coded/modulated OTA message provided by 'modulator 726 to the or UT 704 via transmit antenna 708. Receiver 710 can receive information from receive antenna 706 and can further include a signal receiver (not shown) that receives the uplink data transmitted by UT 704. Additionally, receiver 710 is operatively associated with a demodulator 712 that demodulates the received information. The demodulated symbols are analyzed by a processor 714. The processor 714 is coupled to a memory 716 that stores information related to functions provided by the base station 702. In one example, the stored information can include a number of sets of parameters configured to establish a preferred and non-preference BS (702). In particular, the stored information may include parameters for establishing an HCS that prioritizes the RA BS with respect to the GA BS and uses the RA capabilities of the UT 704 to set relative priority rights, as described herein. Additionally, the processor 714 can be coupled to a selective access module 720. The selective access module 720 can establish and transmit a set of UT parameters that increase the likelihood that the UT 704 will obtain and access the RA BS or reduce the likelihood that the UT 704 will access the GA BS instead of accessing the RA. BS. Additionally, BS 702 can include a registration module 718 that can obtain an access request from UT 704 and allow or deny the access. The access may be based on user profile information (e.g., whether the profile contains a valid subscription) or whether the profile information is included in the CSG associated with BS 702 137601.doc -38 - 201014397. The user profile information can be obtained via a data query module 722. The data query module 722 can be coupled to a network data store (e.g., a VLR) and obtain user profiles from a user profile. The specific user information can be extracted by the analysis module 724. The analysis module 724 parses the user profile. The analysis module 724 can identify subscription information, PLMN IDs associated with the UTs 704, native PLMN zones associated with the UTs 704, UT capabilities (eg, RA capabilities, multi-mode, etc.), and the like. As described herein. Therefore, the data query module 722 and the analysis module 724 can obtain the registration module 718 for allowing or denying the information required for the UT 704 access. 8 illustrates a block diagram of an example system 8A including a UT (e.g., mobile device) 8〇2 that can be configured to interface with a wireless BS 8〇4. The UT 802 can be configured to wirelessly couple with one or more of these wireless networks (e.g., access points). Υτ 8〇2 can receive an OTA signal from the BS 804 on the FL channel and respond with an OTA signal and message on the RL channel, as is known in the art. In addition, 搜寻τ 8〇2 can obtain BS search and access parameterization transmitted by the BS 804. The parameterization may be based on the type of the BS 804 and the neighboring BS (not depicted) (eg, transmission power, access type, reuse type), and is based on the access capability of the device, as herein Described. The UT 802 includes at least one antenna 8〇6 (eg, a transmission receiver including an input interface or a group of such receivers) that receives signals and performs typical actions on the received signals (eg, filtering, amplifying, downconverting) Receiver 808. In accordance with at least some aspects, the processor 812 can selectively analyze portions of the signals received from the demodulation 810 and obtain correlations with a selected base 137601.doc-39. 201014397 platform (804) or base station type. Synchronize and/or control information. In general, antenna 806 and transmitter 832 (collectively referred to as transceivers) can be configured to facilitate wireless data exchange with base station 804. Antenna 806 and receiver 808 can also be coupled to a demodulation transformer 810 that can demodulate the received symbols and provide them to a processor 812 for evaluation. It should be appreciated that the processor 812 can control and/or provide a reference to one or more components (806, 808, 810, 814, 816, 818, 820, 822, 8 24, 826, 828) of the UT 802. In addition, processor 812 can execute one or more modules, applications, engines, or the like (816, 818, 822, 824, 826, 828) that contain information or control related to performing functions of UT 802. For example, 'these functions may include scanning the received wireless signal to find the plmN ID of the operator associated with the BS 804, the distinctive ID of the BS 804, a private network access point (eg, hnB, WiFi access point) The equivalent PlmN ID of the 'WiMAX access point, etc., is parameterized using search and/or access to establish and identify a preferred BS type rather than a non-preferred BS type' or similar operation, as described herein. The UT 802 can additionally include a memory 814 operatively coupled to the processor 812. The memory 814 can store data to be transmitted, received, etc., and instructions adapted to perform wireless communication with the remote device (804) ( 820). Additionally, memory 814 can store the modules, applications, engines, etc. (816, 818, 822, 824, 826, 828) executed by processor 816 above. The UT 802 may additionally include a k-processor 810 that obtains a set of parameters configured to weight the possibility of employing the RA BS or GA BS (804) to interface with a wireless network. In one aspect, signal processor 816 can obtain a parameter that establishes a relatively low threshold 13760I.doc • 40-201014397 value below which the ^^8〇2 is derived from an RA BS ( 8〇4) Service, then the UT 802 searches for non-Han Ba BS. In other aspects, the signal processor 816 can obtain a parameter that establishes a relatively low threshold below which the UT 802 searches for BSs that utilize the frequency of the wireless network employed by the ga BS. According to another aspect, signal processor 816 can obtain RA capabilities stored in s. 814 or provided by BS 804 (e.g., from a user profile stored on a network). A parameterization module 826 can employ the RA capabilities to adjust the UT parameters to increase the likelihood of obtaining and accessing the RA BS if the UT is RA capable, or to reduce the UT 802 without RA capability. The possibility of signaling the RA BS. The parameters obtained by the signal processor 816 can be provided to an access module 818 that uses the parameters to select the analyzed signals for access, handover, or the like. In some aspects of the invention, UT 802 can include a BS preference module 822 that prioritizes BS (804) based on BS type or class. The BS type/category may include an access type, a reuse type, a transmission power type, or the like, as described herein. In particular, the BS preference module 822 can obtain an HCS from the received wireless signals and establish a relative priority level (as provided by the HCS) for different types of BSs (804). According to another aspect, the signal processor 816 A PLMN ID of one of the BSs can be obtained and one of the PLMN IDs reserved for the RA BS. Where the UT 804 is located within one of the home zones defined by the zone PLMN ID, the reserved PLMN ID may be established as the equivalent of the operator's PLMN ID. In this case, the access module 818 can submit the reserved PLMN ID and the zone PLMN ID to the BS 804 to facilitate access to the 137601.doc • 41 - 201014397 BS associated with the reserved PLMN ID. In other aspects, UT 802 can include an access tracking module 824 that records the zone PLMN ID in memory 814 as a preferred or non-preference ID. Specifically, if the BS 804 is the UT's home RA BS (eg, a home HNB), the PLMN ID can be recorded in a cell access history.

• File 820 as the preferred ID. Otherwise, if the BS 804 is a foreign RA. BS, the access tracking module 824 can record the PLMN ID as an excluded ID in the cell access history file 820. The access module 818 can reference the history file 820 to determine whether an access request is submitted to a particular BS (804). A BS containing an excluded ID can be ignored, and a high search/access priority can be given to a BS having a preferred ID. In addition, the parameterization module 826 can increase a threshold. If the PLMN ID of the BS is a preferred zone ID, the UT is in a wireless network utilized by the RA BS. Search or access the BS (804) on the frequency.

In a particular aspect, UT 802 can further include a time-out module 826 that establishes a delay time if BS 804 rejects an access request. For example, this delay prevents the UT 802 from quickly locating the foreign HNB.

Many RA BSs in dense deployments signal. In these aspects, the UT • 804 can store a large amount of battery power in a non-native environment. The foregoing system has been described in terms of interactions between several components, modules, and/or communication interfaces. It will be appreciated that such systems and components/modules/interfaces may include some of the components or subcomponents specified therein, the specified components or subcomponents, and/or additional components. For example, a system can include HNB 210, Internet 240, macro network 602, and UT 802, or a combination of one of its components 137601.doc - 42 - 201014397. Sub-components may also be implemented as being communicatively coupled to other components rather than being included in the components of the previous generation. In addition, it should be noted that one or more components can be combined into a single component that provides a collection of functionality. For example, the data query module 504 can include a data analysis module 514, or the data analysis module 514 can include a data query module 504 to facilitate querying and analyzing the user profile information by means of a single component. The components can also interact with one or more other components not specifically described herein but known to those skilled in the art. In addition, as will be appreciated, the above-disclosed systems and portions of the methods below can include components, sub-components, processes, components, methods, or mechanisms based on artificial intelligence or knowledge or rules (eg, support vector machines, neural networks) Road, expert system, Bayesian inference network, fuzzy logic, data fusion engine, classifier...) or consist of. These components and components in addition to those already described herein may automate the particular mechanisms or processes performed thereby to make portions of such systems and methods more adaptive and effective and intelligent. Exemplary System Described 'See the flowcharts of Figures 9 through 12 for a better understanding of the methods that can be implemented in accordance with the disclosed subject matter. Although the method is shown and described as a series of blocks for the purpose of simplicity of explanation, it should be understood and understood that the claimed matter is not limited by the order of the blocks 'because some blocks may differ from this The order of the order depicted and described herein occurs and/or occurs concurrently with other blocks. Moreover, not all illustrated blocks are required to implement the methods described below. In addition, it should be further appreciated that the methods disclosed below and throughout the specification can be stored on a product of 137601.doc • 43- 201014397 to facilitate the transfer and transfer of such methods to a computer. The term &quot;article&quot; is intended to encompass a computer program accessible from any computer readable device, device in conjunction with a carrier, or storage medium. Figure 9 illustrates a flow diagram of a sample method 9 for weighting υτ access to one or more disparate types of base stations in wireless communication. In the 9〇2 prescription method 900, the transmission base station preference parameterizes to the wireless network of one of the base station services. The parameterization can be established for the base station of the wireless network.

A relative hierarchical structure, which in turn indicates the priority level of various base station types. In an example, the parameterization can establish a high priority for the base station, thereby increasing the possibility that the UT will obtain and access the RA base station or Establishing a low priority for the GA base station' and thus reducing the likelihood that the base station will still be acquired and accessed. In other instances, 'the base station is provided with a higher priority than the RA base station or other base station class, and then the base station and the low power base station are used to implement load balancing, interference reduction, and the like. 0 At _ 'method _ get 4 - access request wireless signal. The access request may include identification information of the device that transmits the signal. In addition, the information may specify the _plmn out or zone/property PLMN ID associated with the device. At 9G6, the method can allow or (4) access-wireless networks based on the identification information provided in the request. In one aspect, permission or rejection can be based on whether the identification of the message is included in the coffee. In other aspects, 'allow or deny access can be based on whether the zone/native PLMN ID is associated with one of the receiving base stations (1). Therefore, the access to the wireless network 137601.doc 201014397 can be adjusted after receiving the information provided in the parameterization of the transmitted round at reference numeral 9〇2. 10 depicts a flow diagram of an example method 1000 for UT access point parameterization in a heterogeneous access point environment. At 1002, method 1000 obtains a wireless signal that includes an access request to the wireless network. At 1004, method 1000 can obtain an action ID of a requesting UT from the wireless signal. At • 1006, method 1000 obtains profile information for the PLMN resource and/or subminiature capability data containing the requesting UT. The profile information/capability data can be obtained from a web server such as an HLR. At 1008, the Φ method 1000 can determine if the requesting UT is configured to access a pico base station. For example, the profile information can be referenced to determine if the requesting UT is associated with a valid HNB subscription. If the requesting UT is determined to be Femto-enabled at 1008, then method 1000 can proceed to 1018. Otherwise, method 1000 proceeds to 1010. At 1010, method 1000 can send a parameterization that establishes a macro base station as a preferred base station. At 1012, a determination is made as to whether the receiving base station is a general access base station. If so, method 1 can proceed to ring 1016 where the requesting UT is allowed to access the wireless network. Otherwise, method 1000 can proceed to 1014 where the requesting UT is denied access to the wireless network. At 1018, method 1000 can compare the PLMN ID reserved for the pico base station with the PLMN ID associated with the requesting UT. At 1020, a determination is made as to whether the PLMN ID of the UT matches the reserved PLMN ID. If so, the Bay ij method 1000 can proceed to 1022. Otherwise, method 1000 proceeds to 1010. At 1022, method 1000 can send a parameterization of establishing a 137601.doc -45-201014397 subminiature base station as a preferred base station. At ^(4), enter 2: The receiving base station is ^ the base of the locality of the request for the request: the judgment. If so, the method 1000 proceeds to 1016 and allows the "green" access. Otherwise, the method i advances to ι 4 where the requested UT access is denied. Figure 11 illustrates A weighted parameterization method for interfacing with an RA or GA base station. The flow chart of the UGG method is at 11.2, and the method 11A can be connected to the wireless L number. At 1104, the method 11 can be derived from the wireless Signal acquisition: a parameterized set 'which will be - a specific type of base station is established as a preferred base. For example, S, compared to a non-preferred base station, the preferred base station can be established as a higher priority base station. Implementing the preference, the parameterization provides a low relative search threshold when tapping to the preferred base station type, below which the (10) search for other base stations and providing when consuming to the non-preferred base station type A high relative search threshold. The search threshold can modify the likelihood that the UT will search for other base stations or search for multiple frequency channels or both in a particular frequency channel. Alternatively, the parameterization can be Provided when connected to the preferred base station type a low relative handover threshold, below the 5 limit, the UT adds other base stations to a valid handover set or performs a handover, and provides a common parent when coupled to the non-preferred base station type The threshold 1100, the method 1100 can use the parameterization to interface with the 2 mobile network, and then search, camp on the preferred base station and seek access to the month (instead of the non-preferred base station). Method 1100 can implement network load balancing between special base station types and reduce the likelihood that the UT will spend processing and signaling resources on non-preferred base stations. 137601.doc •46· 201014397 Figure 12 depicts A flowchart of a sample method 1200 for weighting the UT access function of the UT RA. At 1202, the method 1200 can obtain a wireless signal from a wireless network access point, the wireless signal including a parameterized set, grouped The state is weighted for the search and/or access parameters of the UT within a wireless network. At 1204, method 1200 can extract general access or restricted access weighting parameters from the wireless signal. At 1206, the method 1200 can be judged to connect Receiving the restricted access capability of the UT of the wireless signal. At 1208, the method 1200 can weight the UT parameters to favor the restricted access base station instead of the general access if the UT has limited access capabilities. The base station. The preference parameter may modify the default search and/or access function of the UT to increase the likelihood that the UT is camped on and/or handed over to the restricted access base station. At 1210, the method 1200 may analyze the wireless signal. Obtaining a network PLMN ID data. The PLMN ID data can be compared with a PLMN ID associated with the receiving UT, including a reserved PLMN ID associated with the restricted access base station and a locality associated with the receiving UT PLMN ID. At 1212, if the PLMN ID matches the reserved PLMN ID, the zone PLMN ID, and/or the macro PLMN ID' associated with the UT, then the W method 1200 can search for and/or access the base station broadcasting the PLMN ID. At 1214, method 1200 can record the zone and/or sector information of the base station rejecting the UT's access request. The reject sector/area may be associated with an exclusion list to limit subsequent signaling to such sectors. Additionally, at 1216, method 1200 can revert to the macro PLMN frequency in a delay period after the access denial. Reverting to the macro PLMN frequency can help avoid repeated signaling in a dense foreign restricted access deployment. 13 and 14 respectively depict block diagrams of example systems 丨 300 ' 14 至少 that are implemented at least in part via a mobile network interface and 137601.doc -47- 201014397 to facilitate control of a remote device. For example, the systems 1300, 1400 can reside at least partially within the wireless k-network and/or such as a node, a base station, an access point, a user terminal, a personal computer coupled to a mobile interface card, or the like. Within the transmitter, it will be appreciated that the systems 1300, 1400 are represented as including functional blocks, which may be functional areas representing functions implemented by a processor, software, or combination thereof (eg, firmware). Piece. System 1300 can include means 1302 for obtaining a wireless signal including a network access request. The component 1302 can include a wireless transceiver configured to communicate via one or more wireless communication channels. Additionally, system 1300 can include means for permitting or denying network access requests. Further, system 1300 can include means 13 〇 6 for transmitting a set of τ parameters, the set of parameters increasing UT will search and / Or the possibility of handing over to a particular type of base station. Suitable base station types may include disparate access type base stations (such as restricted or general access), disparate reuse type base stations (such as full reuse or partial reuse), transmission power base stations (such as high, Medium and / or low power transmitters and the like. In a particular aspect, the component 13〇6 can transmit a set of parameters that increase the likelihood that the UT will acquire and access the restricted access base station, or reduce the likelihood that the UT will access the general access base station. . In addition to the foregoing, this parameterization can be transmitted by component 13〇6 to member 〇2 to a particular UT&apos; such as υτ with limited access capability. In such aspects, system 1300 can increase the likelihood that the UT can recognize and hand over to a restricted base station associated with the home. System 1400 can include means 14 〇 2 for receiving no 137601.doc • 48-201014397 line signals transmitted by a wireless network base station. The component 1402 can include an antenna and a signal received by the receiver for down conversion. Additionally, system 14A can include a component 1404 for obtaining a set of parameters that are configured for weighted search and/or access to access points of the wireless network. In some aspects, the component 1404 can extract parameters that are weighted using restricted access or general access base stations to interface with the wireless network. In addition to the foregoing, system 1400 can include means 1406 for employing the set of parameters to implement communications with the network. For example, the component 14〇6 can analyze the signals of the service/station base station and compare these signals to the threshold established by the parameters. As described herein, the thresholds can be weighted to provide a preference for a particular type of base station, such as a restricted access base station or a general access base station. Weighting may increase the likelihood of searching for a base station until a preferred base station is found, or increasing the likelihood of being coupled to the preferred base station once the base station is found. Alternatively or additionally, the weighting may reduce the search for non-preferred base stations. Or maintain the possibility of coupling with a non-preferred base station that is currently serving or being monitored. Thus, system 1400 facilitates network load balancing and prioritizes access terminals to one or more types of wireless network base stations. What has been described above includes examples of aspects of the inventive subject matter. Of course, it is not possible to describe every conceivable combination of components or methods for the purpose of describing the subject matter of the present invention, but those skilled in the art will recognize that many other combinations and permutations of the subject matter of the disclosure are possible. Therefore, the subject matter of the disclosure is intended to cover all such changes, modifications and variations in the spirit and scope of the invention. In addition, the term &quot;includes&quot; has "in the context of the use of the embodiment or the patent application, such as 137601.doc -49· 201014397". It is intended to be inclusive in a manner similar to the term "contains &quot;in &quot;include&quot; as a transitional word used in the request item. [Simplified Schematic] Figure 1 depicts the state of the invention according to the present invention. A block diagram of an example wireless communication environment. Figure 2 illustrates a block diagram of a sample wireless network including a heterogeneous access point base station in accordance with other aspects. Figure 3 illustrates the provision of a picocell in accordance with one or more other aspects. A block diagram of a parametric example system. Figure 4 depicts a block diagram of a sample parameterized record for directing a υτ to a pico or macro access point. Figure 5 illustrates a UT-specific parameterization according to another aspect. Block diagram of an example system. Figure 6 depicts a block diagram of an example wireless network providing an ultra-micro pLMN and a home zone according to other aspects. Figure 7 illustrates an example base that facilitates mobile access in a disparate access point wireless network. A block diagram of a station. Figure 8 depicts a block diagram of a sample τ for accessing a limited access (ra) and general access (GA) base station of a wireless network. Figure 9 illustrates a weighting for use in wireless communications. For one or more Flowchart of a sample method for UT access of a heterogeneous type of base station. Figure 10 depicts a flow diagram of an example method for parameterizing rUt access points in a heterogeneous access point environment. Figure 11 illustrates Flowchart of weighted parameterization to exemplify the example method of the base station 137601.doc -50· 201014397. Figure 2 depicts a flow chart of a sample method for weighting 11-bit access functions based on UT2RA capabilities Figure 13 illustrates a block diagram of a sample system that facilitates weighted parameterization for RA&amp;GA access point wireless networks. Circle 14 depicts a block diagram of an example system that utilizes weighted wireless communication parameterization to access a wireless network. [Main component symbol description]

100 wireless communication system 102a macro cell 102b macro cell 102c macro cell 102d macro cell 102e macro cell 102f macro cell 102g macro cell 104a access point (AP) 104b access point (AP) 104c access point (AP) 104d Access Point (AP) 104e Access Point (AP) 104f Access Point (AP) 104g Access Point (AP) 106a UT 137601.doc • 51- 201014397

106b 106c 106d 106e 106f l〇6g 106h 106i 106j 106k 200 210 220 230 240 250 300 302 304 306 308 310 402

UT

UT

UT

UT

UT

UT

UT

UT

UT

UT

Communication system HNB

UT Indoor/Outdoor Facilities Internet Network Operator Network

System BS UT transceivers that facilitate search or delivery based on BS type or category preferences

Selective Access Module Registration Module Network B S 137601.doc -52- 201014397 404 406 408 410 412 ' 414 • 416 418 • 500

502 504 506 508 510 512 514 516 600 602 604 606A 606B 608A

UT parameterized record HCS parameter UE access type cell search parameter frequency search parameter action selection parameter neighbor cell parameter

System for providing selective parameterization of network BS based on UT specific information BS data query module local network registration core network/user registration core network user profile analysis module registration module network environment floor storage Take points

UT Home HNB Home HNB First home PLMN area 137601.doc -53- 201014397

608B first foreign PLMN zone 608C second foreign PLMN zone 608D second native PLMN zone 700 system 702 base station 704 UT 706 receiving antenna 708 transmission antenna 710 receiver 712 demodulation transformer 714 processor 716 memory 718 registration module 720 Selective access module 722 data query module 724 analysis module 726 modulator 728 transmitter 800 system 802 UT 804 wireless BS 806 antenna 808 receiver 810 demodulation transformer 137601.doc -54- 201014397

812 processor 814 memory 816 signal processor 818 access module 820 cell access history file 822 BS preference module 824 access tracking module 826 parameterization module / timing module 828 parameterization module 832 transmitter 900 Sample method 1000 for weighting UT access to one or more disparate types of base stations in wireless communication Example method 1100 for UT access point parameterization in a heterogeneous access point environment Weighted parameterization for example method 1200 for interfacing with RA or GA base stations 1200 for UT-based RA capability weighted 存取τ access power month &amp; sample method 1300 system 1302 for obtaining wireless access including network access requests The signal component 1304 is used to allow or reject the network access request component 1306 for transmitting a set of UT parameters. The system 137601.doc -55- 201014397 1402 is for receiving wireless signals transmitted by the wireless network base station Component 1404 is used to obtain a set of parameters of component 1406 for employing the set of parameters to implement communication with the network 137601.doc -56-

Claims (1)

201014397 VII. Patent Application Range: 1. A method for providing mobile access in a wireless network, comprising: obtaining a wireless signal including a network access request; allowing or denying the network access request; Transmitting a set of User Terminal (UT) parameters that increase the likelihood that a UT will acquire and access a restricted access base station (RA BS), or reduce the UT's access to a general access (GA) The possibility of the BS instead accesses the ra BS. 2. 3. 4. The method of claim 1, further comprising transmitting a priority hierarchy to a sector of the wireless network, the priority hierarchy indicating that one type of BS is superior to another type of Bs type, or one The frequency channel is superior to one of the other frequency channels. The method of claim 2, wherein the priority hierarchy is a Hierarchical Cell Structure (HCS), and wherein the Hcs or the set of parameters causes at least one parameter to be transmitted to the UT via dedicated signaling. The method of (4) further includes transmitting a low relative threshold parameter below which the neighboring sector of the wireless network is searched by the RA BS service. 5. : Please: The method of item 1, the step-by-step includes the transmission establishment - low relative threshold = parameter, below which the one of the RA positions is newly selected to one of the wireless networks. Neighboring sector. 6. As in the method of request, the method of wilting ^ progress includes the transmission establishing a low relative threshold parameter below the threshold _ 泐晟 by the value of the hopper's search by the UT of the RA BS service with the GABS 7. A method of claim 1, further comprising transmitting a parameter establishing a low relative threshold below which the One of the RA BS services UT searches for a neighboring RA BS at a frequency different from the frequency utilized by the GA BS. 8. The method of claim 1, further comprising transmitting a parameter that establishes a high relative threshold value below which the RA BS is searched by one of the GA BS services. 9. The method of claim 1, further comprising obtaining a UT profile indicating the RA capability or subscription status of the UT and at least one of the following: if the UT is an RA authorized UT, the transmission increases access or handoff A set of parameters that are passed to one of the possibilities of the RA BS; or if the UT is a non-RA authorized UT, transmitting a set of parameters that reduce the likelihood of signaling to the RA BS. 10. The method of claim 9, wherein the RA capabilities provided by the UT profile indicate a priority level of a frequency channel employed by the RA BS or GA BS, the priority level being determined by the set of parameters At least one parameter is used to weight the likelihood of searching for the RA BS or GA BS on the frequency channels. 11. The method of claim 1, further comprising: obtaining a profile of the UT at a sector of the wireless network; identifying a local area ID of the UT from the profile; and if the sector and the The UT's home area shares a common area ID, and a public land mobile network (PLMN) identifier (ID) reserved for the RA BS of the wireless network is established as one of the UT's native PLMN ID equivalents. . 137601.doc 201014397 12. The method of claim 11, further comprising: if the sector shares the common area ID, transmitting the reserved PLMN ID to the UT for BS capture; and if the sector is not shared The common area ID does not transmit the reserved PLMN ID to the UT. 13. The method of claim 1, further comprising: obtaining a home area ID or a closed subscriber group (CSG) ID of the UT; and if the home area ID does not match a sector ID of the sector or if If the CSG ID is not included in one of the CSG lists of the sector, the network access request is rejected. 14. The method of claim 13, further comprising transmitting a parameter to the UT, the parameter establishing a delay time, the UT not performing at least one of the following operations before expiration of the delay time: having a reservation for the RABS Registering on one of the sectors of the PLMN ID; or searching for a sector on one of the frequencies reserved for the RA BS. 15. A base station, comprising: a transceiver that obtains a wireless signal including a network access request; a registration module that allows or denies the network access request; and a selective access A module that employs the transceiver to transmit a set of UT parameters to increase the likelihood that a UT will acquire and access one of the RA BSs or reduce the likelihood that the UT will access a GABS. 1 6. The base station of claim 15 wherein the set of parameters includes a priority hierarchy for the UT configuration, the priority hierarchy indicating at least one of the following: 137601.doc 201014397: if the UT is capable of RA The access priority to the RABS is higher than the access priority to the GABS; or if the UT is not RA-capable, the access priority to the GABS is higher than the access priority to the RABS. 17. The method of claim 16, wherein the priority hierarchy is an HCS, and wherein the selective access module transmits the HCS or at least one of the set of parameters to the UT via dedicated signaling . Φ 18. The base station of claim 15, the set of parameters comprising at least one parameter establishing a low relative threshold below which the UT of the RA BS service searches for the other of the wireless network Sector. 19. The base station of claim 15, the set of parameters comprising at least one parameter establishing a low relative threshold below which one of the RA BS services is added by the UT Sector to a valid handover set. 20. The base station of claim 15, the set of parameters comprising at least one parameter establishing a low relative threshold, below which the UT search is shared with the GA BS by the UT search Other RA BSs of common frequency. 21. The base station of claim 15, the set of parameters comprising at least one parameter establishing a high relative threshold value below which the RA BS is searched by the one of the GA BS services. 22. The base station of claim 15, the set of parameters comprising at least one parameter establishing a low relative threshold below which the UT of the RA BS service is different from being utilized by the GA BS Search for neighboring RA BSs on the frequency of the frequency. 137601.doc 201014397 23. The base station of claim 15 further comprising a data query module, the data query module obtaining a UT profile indicating the RA BS capability of the UT, wherein the selective access module performs At least one of the following: if the UT is an RA capable UT, configuring the set of parameters transmitted to increase the likelihood of obtaining and accessing the RA BS; or • if the UT is not RA capable UT, then configure the set of parameters transmitted to reduce the likelihood of signaling the RA BS. 24. The base station of claim 23, wherein the RA capability provided by the UT profile indicates a priority level of a frequency channel employed by the RA BS or GA BS, the priority level being determined by the set of parameters At least one of the parameters is employed to weight a likelihood of searching for the RA BS or GA BS on the frequency channels. 25. The base station of claim 15 further comprising: a data query module that obtains a profile of the UT; an analysis module that identifies a home location ID of the UT from the profile, and if The BS and the local area of the UT share a common area ID, and then establish one of the PLMN IDs reserved for the stomach RA BS as one of the equivalents of the UT's native PLMN ID. • 26. The base station of claim 25, the selective access module: wherein the BS shares the common area ID, the transceiver is employed to transmit the reserved PLMN ID to the UT for use in the BS And if the BS does not share the common area ID, the reserved PLMN ID is not transmitted to the UT. 27. The base station of claim 15 further comprising an analysis module, the analysis 137601.doc 201014397 module obtaining a home area ID or a CSG ID of the UT from one of the UT profiles, wherein the home code If the zone ID does not match a zone ID of the sector or if the CSG ID is not included in one of the CSG lists of the sector, the registration module rejects the network access request. 28. The base station of claim 27, the set of parameters comprising at least one parameter configured to cause the UT not to perform at least one of the following operations within a specified delay period: having one of the RA BS reservations Registering on one of the PLMN ID sectors; or searching for a sector on one of the frequencies reserved for RABS. 29. Apparatus for providing mobile access in a wireless network, comprising: means for obtaining a wireless signal including a network access request; means for permitting or denying the network access request And a means for transmitting a set of UT parameters, the set of UT parameters increasing a UT will obtain and access one of the RA BS possibilities or reduce the possibility that the UT will access a GA BS. 30. A processor, at least one of which is configured to provide mobile access in a wireless network, the processor comprising: a first module configured to obtain a network access a requested wireless signal; a second module configured to allow or deny the network access request; and a third module configured to transmit a set of UT parameters, the set of UT parameters being incremented by one The UT will acquire and access one of the possibilities of an RA BS or reduce the likelihood that the UT will access a GABS. 137601.doc -6- 201014397 31. A computer program product comprising: a computer readable medium comprising: a first set of codes for causing a computer to obtain a wireless signal including a network access request a second set of codes 'for enabling the computer to allow or deny the network access request; and a third set of codes' for causing the computer to transmit a set of UT parameters, the set of UT parameters being incremented by one UT will be obtained Accessing one of the RA BS possibilities or reducing the possibility that the UT will access a GA BS. 32. A method of accessing a wireless network, comprising: receiving a wireless signal transmitted by a wireless network BS; obtaining a set of parameters 'which are configured to weight a RA BS or GA BS to One of the possibilities of wireless network interfacing; and employing the set of parameters to implement communication with the network. 33. The method of claim 32, further comprising: obtaining a priority hierarchy from the set of parameters and distinguishing the RA BS or the GA BS from the priority or distinguishing the ra BS based on the priority hierarchy and a UT ra capability The priority of one or more frequency channels used by the GA BS. 34. The method of claim 32, further comprising obtaining a parameter from the set of parameters 'the parameter establishes a relatively low threshold' below the threshold, and searching for a non-RABS by one of the RABS services. 35. The method of claim 32, further comprising obtaining a parameter from the set of parameters 'this parameter establishes a relatively low threshold value below which a υτ search utilizes the wireless network by the gabs A frequency of BS. 137601.doc 201014397 36. The method of claim 32, further comprising obtaining a parameter from the set of parameters, the parameter establishing a relatively high threshold, below which the UT searches for the wireless network The RA BS uses one of the frequencies. 37. The method of claim 32, further comprising obtaining at least one of an RA capability of the UT of the wireless network service and at least one of: • if the UT is an RA capable UT, adjusting one of the UT parameters to Increase the likelihood of obtaining and accessing the RA BS; or if the UT is a non-RA capable UT, adjust one of the UT parameters to reduce the likelihood of searching for the RA BS. 3. The method of claim 32, further comprising at least one of the following: if a UT has RA capability, obtaining a PLMN ID of one of the BSs and one of the PLMN IDs reserved for the RA BS as one of the UTs One of the PLMN IDs; or submit the reserved PLMN ID and the zone PLMN ID to the BS in a request to access the wireless network. 39. The method of claim 39, further comprising at least one of: obtaining access to the BS if the BS is a RA BS of the UT; or if the PLMN ID of the area does not match the UT The zone ID is then rejected by one of the requests. 40. The method of claim 39, further comprising at least one of: if the access is obtained, recording the zone PLMN ID as a preferred zone ID; or if the request is rejected, recording the zone PLMN ID as an exclusion District ID of 137601.doc 201014397. 41. The method of claim 40, further comprising adding a threshold if the PLMN ID of the area of the BS is the preferred area ID, below the threshold, the UT is in the wireless network The RA BS utilizes one of the frequencies to search for or access the BS. 42. The method of claim 40, further comprising, if the request is rejected, not searching for the BS on a frequency for one of the RABSs in a delay period. 43. A UT configured to access a wireless network, comprising: • a transceiver that obtains a wireless signal transmitted by a wireless network BS; a signal processor that obtains a set of parameters, The set of parameters are configured to weight one RA BS or GA BS to interface with the wireless network; and an access module that employs the set of parameters to effect communication with the network. 44. The UT of claim 43, further comprising a BS preference module that distinguishes between the RA BS or the GA BS based on a priority hierarchy of the signal obtained by the signal processor and based on the RA capabilities of the UT Priority or distinction between the frequency channels used by these BSs. 45. The UT of claim 43 further obtaining, from the set of parameters, a parameter that establishes a relatively low threshold below which, if the UT is served by an RA BS, Then the UT searches for a non-RA BS. 46. The UT of claim 43 further obtaining a parameter from the set of parameters that establishes a relatively low threshold below the threshold 137601.doc -9-201014397, the UT search A BS that uses one frequency of the wireless network by the GA BS. 47. The UT of claim 43 further obtaining, from the set of parameters, a parameter that establishes a relatively high threshold below which the UT searches for the RABS of the wireless network. Use one of the frequencies. 48. The UT of the request item 43 further obtains the RA capability of the UT, wherein the UT further includes a parameterization module, the parameterization module performing at least one of the following: if the UT is an RA The UT of the capability adjusts one of the parameters of the UT to increase the probability of obtaining and accessing the RABS; or if the UT is a non-RA capable UT, adjusting one of the parameters of the UT to reduce signaling to the RA BS One possibility" 49. According to the UT of claim 43, if the UT has RA capability, the signal processor further obtains the PLMN ID of one of the BSs and the reserved PLMN ID of the UT as one of the UTs. One of the equivalents is the PLMN ID. 50. The UT of claim 43 wherein the access module submits the reserved PLMN ID and the zone PLMN ID to the BS in a request to access the wireless network. 51. The UT of claim 44, further comprising an access tracking module, the access tracking module performing at least one of the following: if the BS is a RA BS of the UT, recording the area PLMN ID as a The preferred zone ID; or if the zone PLMN ID does not match the home zone ID of the UT, the zone PLMN ID is recorded as an excluded zone ID. 52. The UT of claim 45, wherein if the PLMN ID of the BS of the BS is the zone ID of the preference 13760l.doc • 10-201014397, the parameterized module adds a threshold below the threshold. The UT searches for or accesses the BS on one of the frequencies of the wireless network utilized by the ra BS. 53. The UT of claim 45 further includes a time-out module that establishes a delay time 'where the request is rejected', then the access module is not used for one of the RA BSs during the delay time Searching for BS » 54. A device for accessing a wireless network, comprising: means for receiving a wireless signal transmitted by a wireless network BS; such as means for obtaining a set of parameters, The group parameters are configured to weight a possibility of employing an RA BS or GA BS to interface with the wireless network; and means for employing the set of parameters to implement communication with the network. 55. A processor, at least one of which is configured to access a wireless network, the processor comprising: a first module configured to receive a wireless signal transmitted by a wireless network BS; a second module configured to obtain a set of parameters configured to weight a likelihood of using an RA BS or GA BS to interface with the wireless network; and a second mode A group configured to employ the set of parameters to effect communication with the network. 56. A computer program product comprising: a computer readable medium comprising: a first set of codes for causing a computer to receive a wireless signal transmitted by a wireless network BS; 137601.doc 201014397 a second set of codes for causing the computer to obtain a set of parameters configured to weight a possibility of using an RA BS or GA BS to interface with the wireless network; and a third set of codes Used to cause the computer to adopt the set of parameters to implement communication with the network. 137601.doc -12-