Abstract:
Methods and apparatus for selecting a serving sector in a high rate data (HDR) communication system are disclosed. An exemplary HDR communication system defines a set of data rates, at which a sector of an Access Point may send data packets to an Access Terminal. The sector is selected by the Access Terminal to achieve the highest data throughput while maintaining a targeted packet error rate. The Access Terminal employs various methods to evaluate quality metrics of forward and reverse links from and to different sectors, and uses the quality metrics to select the sector to send data packets to the Access Terminal.

Description:
The present Application for Patent is a Continuation and claims priority to U.S. patent application Ser. No. 09/892,378 entitled “METHOD AND APPARATUS FOR SELECTING A SERVING SECTOR IN A DATA COMMUNICATION SYSTEM,” filed Jun. 26, 2001, now U.S. Pat. No. 6,757,520, issued Jun. 29, 2004, and assigned to the assignee hereof and hereby expressly incorporated by reference herein. 

   BACKGROUND 
   1. Field 
   The present invention relates generally to communication systems, and more specifically, to a method and an apparatus for selecting a serving sector in a data communication system. 
   2. Background 
   Communication systems have been developed to allow transmission of information signals from an origination station to a physically distinct destination station. In transmitting information signals from the origination station over a communication channel, the information signal is first converted into a form suitable for efficient transmission over the communication channel. Conversion, or modulation, of the information signal involves varying a parameter of a carrier wave in accordance with the information signal in such a way that the spectrum of the resulting modulated carrier is confined within the communication channel bandwidth. At the destination station the original information signal is replicated from the modulated carrier wave received over the communication channel. Such a replication is generally achieved by using an inverse of the modulation process employed by the origination station. 
   Modulation also facilitates multiple-access, i.e., simultaneous transmission and/or reception, of several signals over a common communication channel. Multiple-access communication systems often include a plurality of remote subscriber units requiring intermittent service of relatively short duration rather than continuous access to the common communication channel. Several multiple-access techniques are known in the art, such as time division multiple-access (TDMA), frequency division multiple-access (FDMA), and amplitude modulation multiple-access (AM). Another type of a multiple-access technique is a code division multiple-access (CDMA) spread spectrum system that conforms to the “TIA/EIA/IS-95 Mobile Station-Base Station Compatibility Standard for Dual-Mode Wide-Band Spread Spectrum Cellular System,” hereinafter referred to as the IS-95 standard. The use of CDMA techniques in a multiple-access communication system is disclosed in U.S. Pat. No. 4,901,307, entitled “SPREAD SPECTRUM MULTIPLE-ACCESS COMMUNICATION SYSTEM USING SATELLITE OR TERRESTRIAL REPEATERS,” and U.S. Pat. No. 5,103,459, entitled “SYSTEM AND METHOD FOR GENERATING WAVEFORMS IN A CDMA CELLULAR TELEPHONE SYSTEM,” both assigned to the assignee of the present invention. 
   A multiple-access communication system may be a wireless or wire-line and may carry voice and/or data. An example of a communication system carrying both voice and data is a system in accordance with the IS-95 standard, which specifies transmitting voice and data over the communication channel. A method for transmitting data in code channel frames of fixed size is described in detail in U.S. Pat. No. 5,504,773, entitled “METHOD AND APPARATUS FOR THE FORMATTING OF DATA FOR TRANSMISSION,” assigned to the assignee of the present invention. In accordance with the IS-95 standard, the data or voice is partitioned into code channel frames that are 20 milliseconds wide with data rates as high as 14.4 Kbps. Additional examples of a communication systems carrying both voice and data comprise communication systems conforming to the “3rd Generation Partnership Project” (3GPP), embodied in a set of documents including Document Nos. 3G TS 25.211, 3G TS 25.2 12, 3G TS 25.213, and 3G TS 25.214 (the W-CDMA standard), or “TR-45.5 Physical Layer Standard for cdma2000 Spread Spectrum Systems”(the IS-2000 standard). 
   In a multiple-access communication system, communications between users are conducted through one or more base stations. A first user on one subscriber station communicates to a second user on a second subscriber station by transmitting data on a reverse link to a base station. The base station receives the data and can route the data to another base station. The data is transmitted on a forward link of the same base station, or the other base station, to the second subscriber station. The forward link refers to transmission from a base station to a subscriber station and the reverse link refers to transmission from a subscriber station to a base station. Likewise, the communication can be conducted between a first user on one mobile subscriber station and a second user on a landline station. A base station receives the data from the user on a reverse link, and routes the data through a public switched telephone network (PSTN) to the second user. In many communication systems, e.g., IS-95, W-CDMA, IS-2000, the forward link and the reverse link are allocated separate frequencies. 
   An example of a data only communication system is a high data rate (HDR) communication system that conforms to the TIA/EIA/IS-856 industry standard, hereinafter referred to as the IS-856 standard. This HDR system is based on a communication system disclosed in co-pending application Ser. No. 08/963,386, entitled “METHOD and apparatus FOR HIGH RATE PACKET DATA transmission,” filed Nov. 3, 1997, assigned to the assignee of the present invention. The HDR communication system defines a set of data rates, ranging from 38.4 kbps to 2.4 Mbps, at which an access point (AP) may send data to a subscriber station (access terminal, AT). Because the AP is analogous to a base station, the terminology with respect to cells and sectors is the same as with respect to voice systems. 
   A significant difference between voice services and data services is the fact that the former imposes stringent and fixed delay requirements. Typically, the overall one-way delay of speech frames must be less than 100 ms. In contrast, the data delay can become a variable parameter used to optimize the efficiency of the data communication system. Specifically, more efficient error correcting coding techniques which require significantly larger delays than those that can be tolerated by voice services can be utilized. An exemplary efficient coding scheme for data is disclosed in U.S. patent application Ser. No. 08/743,688, entitled “SOFT DECISION OUTPUT DECODER FOR DECODING CONVOLUTIONALLY ENCODED CODEWORDS,” filed Nov. 6, 1996, now U.S. Pat. No. 5,933,462, issued Aug. 3, 1999, assigned to the assignee of the present invention. 
   Another significant difference between voice services and data services is that the former requires a fixed and common grade of service (GOS) for all users. Typically, for digital systems providing voice services, this translates into a fixed and equal transmission rate for all users and a maximum tolerable value for the error rates of the speech frames. In contrast, for data services, the GOS can be different from user to user and can be a parameter optimized to increase the overall efficiency of the data communication system. The GOS of a data communication system is typically defined as the total delay incurred in the transfer of a predetermined amount of data, hereinafter referred to as a data packet. 
   Yet another significant difference between voice services and data services is that the former requires a reliable communication link. When a mobile station, communicating with a first base station, moves to the edge of the associated cell or sector, the mobile station initiates a simultaneous communication with a second base station. This simultaneous communication, when the mobile station receives a signal carrying equivalent information from two base stations, termed soft handoff, is a process of establishing a communication link with the second base station while maintaining a communication link with the first base station. When the mobile station eventually leaves the cell or sector associated with the first base station and breaks the communication link with the first base station, it continues the communication on the communication link established with the second base station. Because the soft handoff is a “make before break” mechanism, the soft handoff minimizes the probability of dropped calls. The method and system for providing a communication with a mobile station through more than one base station during the soft handoff process are disclosed in U.S. Pat. No. 5,267,261, entitled “MOBILE STATION ASSISTED SOFT HANDOFF IN A CDMA CELLULAR COMMUNICATIONS SYSTEM,” assigned to the assignee of the present invention. Softer handoff is the process whereby the communication occurs over multiple sectors that are serviced by the same base station. The process of softer handoff is described in detail in U.S. patent application Ser. No. 08/763,498, entitled “METHOD AND APPARATUS FOR PERFORMING HANDOFF BETWEEN SECTORS OF A COMMON BASE STATION,” filed Dec. 11, 1996, now U.S. Pat. No. 5,933,787, issued Aug. 3, 1999, assigned to the assignee of the present invention. Thus, both soft and softer handoff for voice services result in redundant transmissions from two or more base stations to improve reliability. 
   This additional reliability is not required for data transmission because the data packets received in error can be retransmitted. For data services, the parameters, which measure the quality and effectiveness of a data communication system, are the transmission delay required to transfer a data packet and the average throughput rate of the system. Transmission delay does not have the same impact in data communication as in voice communication, but the transmission delay is an important metric for measuring the quality of the data communication system. The average throughput rate is a measure of the efficiency of the data transmission capability of the communication system. Consequently, the transmit power and resources used to support soft handoff can be more efficiently used for transmission of additional data. To maximize the throughput, the transmitting sector should be chosen in a way that maximizes the forward link throughput as perceived by the Access Terminal (AT). 
   There is, therefore, a need in the art for a method and an apparatus for selecting a sector in a data communication system that maximizes the forward link throughput as perceived by the AT. 
   SUMMARY 
   In one aspect of the invention, the above-stated needs are addressed by determining at the remote station a quality metric of a forward link for each sector in the remote station&#39;s list, determining a quality metric of a reverse link to each sector in the remote station&#39;s list, and directing communication between the remote station and one sector from the sectors in the remote station&#39;s list in accordance with said determined quality metric of a forward link and said determined quality metric of a reverse link. The quality metric of a forward link for each sector in the remote station&#39;s list may be determined by measuring a signal-to interference and signal-to-noise ratio of the forward link. The quality metric of a reverse link to each sector in the remote station&#39;s list may be determined by processing at the remote station the forward link from each sector in the remote station&#39;s list. The signal processed may be obtained by measuring at each sector the quality metric of the reverse link, processing the quality metric to provide an indicator of the quality metric, and providing the indicator on a forward link. The communication between the remote station and one sector from the sectors in the remote station&#39;s list may be directed in accordance with said determined quality metric of a forward link and said determined quality metric of a reverse link by assigning credits to each sector in the remote station&#39;s list, except a sector currently serving the remote station in accordance with said determined quality metric of a forward link and said determined quality metric of the reverse link, and directing communication between the remote station and one sector from the sectors in the remote station&#39;s list in accordance with said assigned credits. 
   In another aspect of the invention, the above-stated needs are addressed by determining at the remote station a quality metric of a forward link for each sector in the remote station&#39;s list; and directing communication between the remote station and one sector from the sectors in the remote station&#39;s list in accordance with said determined quality metric of a forward link. The quality metric of a forward link for each sector in the remote station&#39;s list may be determined by measuring a signal-to-interference and signal-to-noise ratio of the forward link. The communication between the remote station and one sector from the sectors in the remote station&#39;s list may be directed in accordance with said determined quality metric of a forward link by assigning credits to each sector in the remote station&#39;s list, except a sector currently serving the remote station in accordance with said determined quality metric of a forward link and directing communication between the remote station and one sector from the sectors in the remote station&#39;s list in accordance with said assigned credits. 

   
     BRIEF DESCRIPTION OF THE DRAWINGS 
       FIG. 1  illustrates a conceptual diagram of a High Data Rate (HDR) communication system; 
       FIG. 2  illustrates an exemplary forward link waveform; 
       FIG. 3  illustrates an Access Point processing of a data request (DRC) for a Message Based DRC Lock method; 
       FIG. 4  illustrates an Initialization phase at an Access Terminal for the Message Based DRC Lock method; 
       FIG. 5  illustrates a Credit Accumulation phase at the Access Terminal for the Message Based Data Request Channel Lock method; 
       FIG. 6  illustrates a Decision phase at the Access Terminal for the Message Based DRC Lock method; 
       FIGS. 7 and 8  illustrate the Decision phase for a sector selection when the DRC of a current serving sector is “in-lock” for the Message Based DRC Lock method; 
       FIG. 9  illustrates the Decision phase for the sector selection when the DRC of the current serving sector is “out-of-lock” for the Message Based DRC Lock method; 
       FIG. 10  illustrates the Credit Accumulation phase at the Access Terminal for the Message Based DRC Lock method in accordance with another embodiment; 
       FIG. 11  illustrates the Decision phase for sector selection when the DRC from the current serving sector is “in-lock” for the Message Based DRC Lock method in accordance with another embodiment; 
       FIG. 12  illustrates the Credit Accumulation phase at the Access Terminal for the Message Based DRC Lock method in accordance with yet another embodiment; 
       FIG. 13  illustrates the Access Point processing of the DRC for a Punctured DRC Lock Bit method; 
       FIG. 14  illustrates a Demodulation phase for the Punctured DRC Lock Bit method; 
       FIG. 15  illustrates an Accreditation phase for the Punctured DRC Lock Bit method; 
       FIG. 16  illustrates a Certification phase for the Punctured DRC Lock Bit method; and 
       FIG. 17  illustrates a Decision phase for the Punctured DRC Lock Bit method. 
   

   DETAILED DESCRIPTION 
   The word “exemplary” is used exclusively herein to mean “serving as an example, instance, or illustration.” Any embodiment described herein as “exemplary” is not necessarily to be construed as preferred or advantageous over other embodiments. 
   The term packet is used exclusively herein to mean a group of bits, including data (payload) and control elements, arranged into a specific format. The control elements comprise, e.g., a preamble, a quality metric, and others known to one skilled in the art. Quality metric comprises, e.g., a cyclical redundancy check (CRC), a parity bit, and others known to one skilled in the art. 
   The term access network is used exclusively herein to mean a collection of access points (APs) and one or more access point controllers. The access network transports data packets between multiple access terminals (ATs). The access network may be further connected to additional networks outside the access network, such as a corporate intranet or the Internet, and may transport data packets between each access terminal and such outside networks. 
   The term base station, referred to herein as an AP in the case of an HDR communication system, is used exclusively herein to mean the hardware with which subscriber stations communicate. Cell refers to the hardware or a geographic coverage area, depending on the context in which the term is used. A sector is a partition of a cell. Because a sector has the attributes of a cell, the teachings described in terms of cells are readily extended to sectors. 
   The term subscriber station, referred to herein as an AT in the case of an HDR communication system, is used exclusively herein to mean the hardware with which an access network communicates. An AT may be mobile or stationary. An AT may be any data device that communicates through a wireless channel or through a wired channel, for example using fiber optic or coaxial cables. An AT may further be any of a number of types of devices including, but not limited to a PCT Card, a compact flash, an external or internal modem, or a wireless or wireline phone. An AT that is in the process of establishing an active traffic channel connection with an AP is said to be in a connection setup state. An AT that has established an active traffic channel connection with an AP is called an active AT and is said to be in a traffic state. 
   The term communication channel/link is used exclusively herein to mean a single route over which a signal is transmitted described in terms of modulation characteristics and coding, or a single route within the protocol layers of either the AP or the AT. 
   The term reverse channel/link is used exclusively herein to mean a communication channel/link through which the AT sends signals to the AP. 
   A forward channel/link is used exclusively herein to mean a communication channel/link through which an AP sends signals to an AT. 
   The term softer handoff is used exclusively herein to mean a communication between a subscriber station and two or more sectors, wherein each sector belongs to the same cell. In the context of the IS-95 standard, the reverse link communication is received by both sectors, and the forward link communication is simultaneously carried on one of the two or more sectors&#39; forward links. In the context of the IS-856 standard, data transmission on the forward link is non-simultaneously carried out between one of the two or more sectors and the AT. 
   The term softer handoff is used exclusively herein to mean a communication between a subscriber station and two or more sectors, wherein each sector belongs to the same cell. In the context of the IS-95 standard, the reverse link communication is received by both sectors, and the forward link communication is simultaneously carried on one of the two or more sectors&#39; forward links. In the context of the IS-856 standard, data transmission on the forward link is non-simultaneously carried out between one of the two or more sectors and the AT. 
   The term re-pointing is used exclusively herein to mean a selection of a sector that is a member of an AT&#39;s active list, wherein the sector is different than a currently selected sector. 
   The term soft/softer handoff delay is used exclusively herein to indicate the minimum interruption in service that a subscriber station would experience following a handoff to another sector. Soft/softer handoff delay is determined based on whether the sector, (currently not serving the subscriber station, or the non-serving sector) to which the subscriber station is re-pointing is part of the same cell as the current serving sector. If the non-serving sector is in the same cell as the serving sector, then the softer handoff delay is used, and if the non-serving sector is in a cell different from the one that the serving sector is part of, then the soft handoff delay is used. 
   The term non-homogenous soft/softer handoff delay is used exclusively herein to indicate that the soft/softer handoff delays are sector specific, and therefore may not uniform across the sectors of an Access Network. 
   The term credit is used exclusively herein to mean a dimensionless attribute indicating a quality metric of a reverse link, a quality metric of a forward link, or a composite quality metric of both forward and reverse links. 
   The term erasure is used exclusively herein to mean failure to recognize a message. 
   The term outage is used exclusively herein to mean a time interval during which the likelihood that a subscriber station will receive service is reduced. 
   The term fixed rate mode is used exclusively herein to mean that a particular sector transmits a Forward Traffic Channel to the AT at one particular rate. 
   Description 
     FIG. 1  illustrates a conceptual diagram of an HDR communication system capable of performing re-pointing in accordance with embodiments of the present invention, e.g., a communication system in accordance with the IS-856 standard. An AP  100  transmits data to an AT  104  over a forward link  106 ( 1 ) and receives data from the AT  104  over a reverse link  108 ( 1 ). Similarly, an AP  102  transmits data to the AT  104  over a forward link  106 ( 2 ) and receives data from the AT  104  over a reverse link  108 ( 2 ). In accordance with one embodiment, data transmission on the forward link occurs from one AP to one AT at or near the maximum data rate that can be supported by the forward link and the communication system. Other channels of the forward link, e.g., control channel, may be transmitted from multiple APs to one AT. Reverse link data communication may occur from one AT to one or more APs. The AP  100  and the AP  102  are connected to a controller  110  over backhauls  112 ( 1 ) and  112 ( 2 ). The term backhaul is used to mean a communication link between a controller and an AP. Although only two ATs and one AP are shown in  FIG. 1 , one of ordinary skill in the art recognizes that this is for pedagogical purposes only, and the communication system can comprise a plurality of ATs and APs. 
   Initially, the AT  104  and one of the APs, e.g., the AP  100 , establish a communication link using a predetermined access procedure. In this connected state, the AT  104  is able to receive data and control messages from the AP  100  and is able to transmit data and control messages to the AP  100 . The AT  104  continually searches for other APs that could be added to the AT  104  active set. The active set comprises a list of the APs capable of communication with the AT  104 . When such an AP is found, the AT  104  calculates a quality metric of the AP&#39;s forward link, which in one embodiment comprises a signal-to-interference-and-noise ratio (SINR). In one embodiment, the AT  104  searches for other APs and determines the AP&#39;s SINR in accordance with a pilot signal. Simultaneously, the AT  104  calculates the forward link quality metric for each AP in the AT  104  active set. If the forward link quality metric from a particular AP is above a predetermined add threshold or below a predetermined drop threshold for a predetermined period of time, the AT  104  reports this information to the AP  100 . Subsequent messages from the AP  100  direct the AT  104  to add to or to delete from the AT  104  active set the particular AP. 
   The AT  104  selects a serving AP from the active set based on a set of parameters. The term serving AP refers to an AP that a particular AT selected for data communication or an AP that is communicating data to the particular AT. The set of parameters can comprise present and previous SINR measurements, a bit-error-rate and/or a packet-error-rate, and other parameters known to one skilled in the art. In one embodiment, the serving AP is selected in accordance with the largest SINR measurement. The AT  104  then transmits to the selected AP a data request message (DRC message) on the data request channel (DRC channel). The DRC message can contain the requested data rate or, alternatively, an indication of the quality of the forward link, e.g., the measured SINR, the bit-error-rate, or the packet-error-rate. In one embodiment, the AT  104  can direct the transmission of the DRC message to a specific AP by the use of a Walsh code, which uniquely identifies the specific AP. The DRC message symbols are exclusively OR&#39;ed (XOR) with the unique Walsh code. The XOR operation is referred to as Walsh-covering of a signal. Since each AP in the active set of the AT  104  is identified by a unique Walsh code, only the selected AP which performs the identical XOR operation as that performed by the AT  104  with the correct Walsh code can correctly decode the DRC message. 
   The data to be transmitted to the AT  104  arrive at the controller  110 . In accordance with one embodiment, the controller  110  sends the data to all APs in AT  104  active set over the backhaul  112 . In another embodiment, the controller  110  first determines which AP was selected by the AT  104  as the serving AP, and then sends the data to the serving AP. The data are stored in a queue at the AP(s). A paging message is then sent by one or more APs to the AT  104  on respective control channels. The AT  104  demodulates and decodes the signals on one or more control channels to obtain the paging messages. 
   At each time time-slot, the AP can schedule data transmission to any of the ATs that received the paging message. An exemplary method for scheduling transmission is described in U.S. Pat. No. 6,229,795, entitled “System for allocating resources in a communication system,” assigned to the assignee of the present invention. The AP uses the rate control information received from each AT in the DRC message to efficiently transmit forward link data at the highest possible rate. In one embodiment, the AP determines the data rate at which to transmit the data to the AT  104  based on the most recent value of the DRC message received from the AT  104 . Additionally, the AP uniquely identifies a transmission to the AT  104  by using a spreading code which is unique to that mobile station. In the exemplary embodiment, this spreading code is the long pseudo noise (PN) code, which is defined by the IS-856 standard. 
   The AT  104 , for which the data packet is intended, receives the data transmission and decodes the data packet. In one embodiment, each data packet is associated with an identifier, e.g., a sequence number, which is used by the AT  104  to detect either missed or duplicate transmissions. In such an event, the AT  104  communicates via the reverse link data channel the sequence numbers of the missing data units. The controller  110 , which receives the data messages from the AT  104  via the AP communicating with the AT  104 , then indicates to the AP what data units were not received by the AT  104 . The AP then schedules a retransmission of such data units. 
   When the communication link between the AT  104  and the AP  100 , operating in the variable rate mode, deteriorates below required reliability level, the AT  104  first attempts to determine whether communication with another AP in the variable rate mode supporting an acceptable rate data is possible. If the. AT  104  ascertains such an AP (e.g., the AP  102 ), a re-pointing to the AP  102 , therefore, to a different communication link occurs, and the data transmissions continue from the AP  102  in the variable rate mode. The above-mentioned deterioration of the communication link can be caused by, e.g., the AT  104  moving from a coverage area of the AP  100  to the coverage area of the AP  102 , shadowing, fading, and other reasons known to one skilled in the art. Alternatively, when a communication link between the AT  104  and another AP (e.g., the AP  102 ) that may achieve higher throughput rate that the currently used communication link becomes available, a re-pointing to the AP  102 , therefore, to a different communication link occurs, and the data transmissions continue from the AP  102  in the variable rate mode. If the AT  104  fails to detect an AP that can operate in the variable rate mode and support an acceptable data rate, the AT  104  transitions into a fixed rate mode. 
   In one embodiment, the AT  104  evaluates the communications links with all candidate APs for both variable rate data and fixed rate data modes, and selects the AP, which yields the highest throughput. 
   The AT  104  will switch from the fixed rate mode back to the variable rate mode if the sector is no longer a member of the AT  104  active set. 
   In the exemplary embodiment, the above described the fixed rate mode and associated methods for transition to and from the fixed mode are similar to those disclosed in detail in U.S. Pat. No. 6,205,129, entitled “METHOD AND APPARATUS FOR VARIABLE AND FIXED FORWARD LINK RATE CONTROL IN A MOBILE RADIO COMMUNICATION SYSTEM,” assigned to the assignee of the present invention. Other fixed rate modes and associated methods for transition to and from the fixed mode can also be contemplated and are within the scope of the present invention. 
   One skilled in the art recognizes that an AP can comprise one or more sectors. In the description above, the term AP was used generically to allow clear explanation of basic concepts of the HDR communication system. However, one skilled in the art can extend the explained concepts to AP comprising any number of sectors. Consequently, the concept of sector will be used throughout the rest of the document. 
   Forward Link Structure 
     FIG. 2  illustrates an exemplary forward link waveform  200 . For pedagogical reasons, the forward link waveform  200  is modeled after a forward link waveform of the above-mentioned HDR system. However, one of ordinary skill in the art will understand that the teaching is applicable to different waveforms. Thus, for example, in one embodiment the waveform does not need to contain pilot signal bursts, and the pilot signal can be transmitted on a separate channel, which can be continuous or bursty. The forward link waveform  200  is defined in terms of frames. A frame is a structure comprising 16 time-slots  202 , each time-slot  202  being 2048 chips long, corresponding to a 1.66-ms time-slot duration, and, consequently, a 26.66-ms frame duration. Each time-slot  202  is divided into two half-time-slots  202 A and  202 B, with pilot bursts  204 A and  204 B transmitted within each half-time-slot  202 A and  202 B. In the exemplary embodiment, each pilot burst  204 A and  204 B is 96 chips long, and is centered at the mid-point of its associated half-time-slot  202 A and  202 B. The pilot bursts  204 A and  204 B comprise a pilot channel signal covered by a Walsh cover with index  0 . A forward medium access control channel (MAC)  206  forms two bursts, which are transmitted immediately before and immediately after the pilot burst  204  of each half-time-slot  202 . In the exemplary embodiment, the MAC is composed of up to 64 code channels, which are orthogonally covered by 64-ary Walsh codes. Each code channel is identified by a MAC index, which has a value between 1 and 64, and identifies a unique 64-ary Walsh cover. A reverse power control channel (RPC) is used to regulate the power of the reverse link signals for each subscriber station. The RPC is assigned to one of the available MACs with MAC index between 5 and 63. The MAC with MAC index  4  is used for a reverse activity channel (RA), which performs flow control on the reverse traffic channel. The forward link traffic channel and control channel payload is sent in the remaining portions  208 A of the first half-time-slot  202 A and the remaining portions  208 B of the second half-time-slot  202 B. 
   Re-Pointing Using a DRC Lock Indication—Introduction 
   A re-pointing decision is made by the AT  104  in accordance with a condition of a forward link, a condition of a reverse link, or a condition of both a forward link and a reverse link. As described above, the AT  104  determines a forward link quality metric directly, e.g., by measuring the forward link SINR. The quality metric of a reverse link may comprise a reverse link SINR, a DRC erasure rate, a filtered RPC mean, and other quality metrics known to one skilled in the art. 
   As discussed, the AT  104  identifies a serving sector of a particular AP and transmits a DRC message on a DRC channel on a reverse link. The reverse link carrying the DRC messages between the AT  104  and the serving sector is subject to various factors that change characteristics of the communication channel. In a wireless communications systems these factors comprise, but are not limited to: fading, noise, interference from other terminals, and other factors known to one skilled in the art. The DRC message is protected against the changing characteristics of the communication channel by various methods, e.g., message length selection, encoding, symbol repetition, interleaving, transmission power, and other methods known to one of ordinary skill in the art. However, these methods impose performance penalties, e.g., increased overhead, thus, decreased throughput, increased power consumption, increased peak-to-average power, increased power amplifier backoff, more expensive power amplifiers, and other penalties known to one skilled in the art. Therefore, an engineering compromise between a reliability of message delivery and an amount of overhead must be made. Consequently, even with the protection of information, the conditions of the communication channel can degrade to the point at which the serving sector possibly cannot decode (erases) some of the DRC messages. Therefore, the DRC erasure rate is directly related to the conditions of the reverse link, and the DRC erasure rate is a good quality metric of the reverse link. 
   However, the AT  104  can directly determine neither the reverse link SINR nor the DRC erasure rate. Both the reverse link SINR and the DRC erasure rate may be directly determined by the sectors in the AT  104  active set. The sector(s) then supplies the AT  104  with the determined values of the reverse link SINR or the DRC erasure rate via a feedback loop. In order for a sector to transmit accurate information regarding the reverse link SINR or DRC erasure rate, the sector must use some forward link capacity. In order to minimize the impact on forward link capacity, the reverse link SINR or the DRC erasure rate is sent with very low granularity. In one embodiment, the granularity is one bit. Furthermore, a consideration of a feedback loop speed versus a performance of the Reverse Link Traffic Channel performance must be made. 
   Therefore, in a Message Based DRC Lock embodiment, each sector in the AT  104  active set monitors the DRC channel and evaluates an erasure rate of the DRC messages. Each sector then sets a DRC Lock Bit for the AT  104  in accordance with the evaluated erasure rate. In one embodiment, the DRC Lock Bit set to one value, e.g., one (“in-lock”), indicates that the DRC erasure rate is acceptable; the DRC Lock Bit set to a second value, e.g., zero (“out-of-lock”), indicates that the DRC erasure rate is unacceptable. The serving sector then sends the DRC Lock Bit to the AT  104  in a message on a control channel. The control channel for a communication system in accordance with the IS-856 standard has a period of 426 ms. 
   In a Punctured DRC Lock embodiment, the DRC Lock Bit is updated at a rate different from the control channel period and punctured into an RPC channel one or more times every frame. The term punctured is used herein to mean sending the DRC Lock Bit instead of a RPC bit. 
   The AT  104  then uses the reverse link quality metric together with the forward link quality metric to make a re-pointing decision. 
   Re-Pointing with a Message Based DRC Lock 
   Access Point Processing 
   The processing method at the AP in accordance with one embodiment comprises three phases. In the first phase, mapping a DRC Erasure and/or a valid DRC to a binary form generates a DRC Erasure Bit. In the second phase, processing the DRC Erasure Bits generates a DRC erasure rate. In the third phase, sampling the processed DRC erasure rate every control channel period generates a DRC Lock Bit. 
   The above-described phases one and two are repeated every time-slot by every sector in the AT  104  active set, as illustrated in  FIG. 3  in accordance with an embodiment. The method starts in step  302 . The method continues in step  304 . 
   In step  304 , the AP receives an updated DRC. The method continues in step  306 . 
   In step  306 , the AP tests the updated DRC. If the DRC was erased, the method continues in step  308 , otherwise, the method continues in step  310 . 
   In step  308 , the DRC Erasure Bit is assigned a value of one. The method continues in step  312 . 
   In step  310 , the DRC Erasure Bit is assigned a value of zero. The method continues in step  312 . 
   In step  312 , the DRC Erasure Bit is processed to generate a DRC erasure rate. In one embodiment, the processing comprises filtering by a filter with a pre-determined time constant. In one embodiment, the filter is realized in a digital domain. The value of the pre-determined time constant may be established in accordance with system simulation, by experiment or via other engineering methods known to one of ordinary skill in the art as an optimum in accordance with: 
   reliability of an estimate ensuing from a choice of the time constant, and 
   latency of an estimate ensuing from the choice of the time constant. 
   The method continues in step  314 . 
   In step  314 , the system time is tested to establish the beginning of a control channel capsule. If the test is positive, the method continues in step  316 , otherwise the method returns to step  304 . 
   Steps  316  through  326  introduce hysteresis rules for generating the DRC Lock Bit. The hysteresis is introduced to avoid rapid re-pointing when the channel SINR varies rapidly. The hysteresis rules are as follows: 
   If the DRC Lock Bit is currently set to one, then the filtered DRC erasure rate must exceed first DRC erasure threshold (DRC_Erasure_Th2) for the DRC Lock Bit to be set to zero. 
   If the DRC Lock Bit is currently set to zero, then the Filtered DRC Erasure rate has to be below a second pre-determined DRC erasure threshold (DRC_Erasure_Th1) for the DRC Lock to be set to one. 
   In one embodiment, the values DRC_Erasure_Th1 and DRC —Erasure _Th2 are pre-determined in accordance with the communication system simulation, by experiment or other engineering methods known to one of ordinary skill in the art. In another embodiment, the values DRC_Erasure_Th1 and DRC_Erasure_Th2 are changed in accordance with the change of the conditions of the communication link. In either embodiment, the values of DRC_Erasure_Th1 and DRC_Erasure_Th2 are selected to optimize the following requirements to: 
   minimize the dead-zone (when the DRC Lock Bit is not updated); and 
   transmit the most current reverse link channel state information to the AT. 
   In step  316 , the current DRC Lock Bit value is compared to 1. If the DRC Lock Bit value equals 1, the method continues in step  320 ; otherwise, the method continues in step  318 . 
   In step  318 , the DRC erasure rate is compared to the DRC_Erasure_Th1. If the DRC erasure rate is less than the DRC_Erasure Th1, the method continues in step  324 ; otherwise, the method continues in step  322 . 
   In step  320 , the DRC erasure rate is compared to the DRC_Erasure_Th2. If the DRC erasure rate is less than the DRC_Erasure_Th2, the method continues in step  324 ; otherwise, the method continues in step  326 . 
   In step  322 , the DRC Lock Bit value is set to 0. The method continues in step  328 . 
   In step  324 , the DRC Lock Bit value is set to 1. The method continues in step  328 . 
   In step  326 , the DRC Lock Bit value is set to 0. The method continues in step  328 . 
   In step  328 , the DRC Lock Bit is set at the appropriate position of the control channel message. The method returns to step  304 . 
   Access Terminal Processing 
   As discussed, in one embodiment, the AT is assumed to be able to demodulate a control channel from only one sector in the AT&#39;s active set. The processing method at the AT in accordance with the embodiment comprises the phases of (i) Initialization, (ii) Credit Accumulation, and (iii) Decision. 
   Initialization 
   During the initialization stage, the AT  104  selects a sector with the best forward link quality metric, i.e., the highest SINR, as the serving sector. The AT  104  sets the DRC for the selected sector “in-lock” and initializes credits for all non-serving sectors to zero. 
   In one embodiment, two types of credits are defined—switching credits and monitoring credits. The credits are described in more details in the Credit Accumulation paragraph. 
   The initialization phase in accordance with one embodiment is illustrated in  FIG. 4 . The method starts in step  402 . The method continues in step  404 . 
   In step  404 , the AT selects a sector with the best forward link quality metric as the serving sector, and sets the sector&#39;s DRC “in-lock.” The method continues in step  406 . 
   In step  406 , a variable count is set to one. The method continues in step  408 . 
   In step  408 , the variable count is tested against an active set size. If the variable count is greater than the active set size, the method continues in an accumulation phase; otherwise, the method continues in step  410 . 
   In step  410 , the inquiry is made whether the sector designated by the variable count is the current serving sector as selected in step  404 . If the test is positive, the method continues in step  414 ; otherwise, the method continues in step  412 . 
   In step  412 , monitoring credits for a non-serving sector (CM_NS) and switching credits for a non-serving sector (CS_NS) are set to zero. The method continues in step  414 . 
   In step  414 , the variable count is incremented, and the method returns to step  408 . 
   Credit Accumulation 
   As discussed, two types of credits are defined—switching credits and monitoring credits in accordance with one embodiment. Switching credits are used to qualify a non-serving sector for re-pointing, if the DRC of the non-serving sector is “in lock” with a pre-determined probability. Thus, CS_NS are incremented if: 
   a forward link SINR of the non-serving sector (FL_NS) is greater than a forward link SINR of the current serving sector (FL_SS) modified by a pre-determined value (FL_SINR_Th); and 
   a filtered RPC mean for the non-serving sector (RL_NS) is below a pre-determined threshold (RPC_Th). 
   CS_NS are decremented if the above conditions are not satisfied. 
   The pre-determined value FL_SINR_Th is selected so that re-pointing to another sector results in an increase in forward link SINR and, consequently, in an increase in an average requested data rate. 
   The pre-determined threshold RPC_Th is chosen so that the AP&#39;s DRC is “in-lock” with a probability PIL when the filtered RPC mean is below the RPC_Th. The relationship between the probability PIL and the threshold is determined in accordance with simulations, laboratory tests, field trails, and other engineering methods. The RPC_Th is chosen to be conservative to minimize the cost associated with re-pointing the DRC to a sector with the DRC “out-of-lock.” If the AT did re-point to a sector with the DRC “out-of-lock,” not only would the AT experience degraded throughput, but also a higher outage probability. The method can afford to select the RPC_Th conservatively because the monitoring credits are used to re-point to sectors with filtered RPC mean greater than the threshold but with DRC “in-lock.” In one embodiment, the RPC_Th is chosen such that there is a less than 1% probability that the DRC is “out-of-lock” when the filtered RPC Mean is below the RPC_Th for any given channel conditions. 
   In one embodiment, the minimum value for the credits (both switching and monitoring) is zero, and the maximum for the credits is equal to a soft handoff delay or a softer handoff delay. The delay used is determined based on whether or not the non-serving sector is in the same cell as the serving sector. If the non-serving sector is in the same cell as the serving sector, then the softer handoff delay is used, and if the non-serving sector is in a cell different from the one that the serving sector is part of, then the soft-handoff delay is used. 
   It is possible that a filtered RPC mean for the non-serving sector is above RPC_Th, and the DRC is “in-lock” for the non-serving sector. Considering the rules for incrementing the switching credits, the switching credits will not be incremented, although a forward link SINR of the non-serving sector is greater than a forward link SINR of the current serving sector by FL_SINR_Th. Consequently, a throughput of the system is not optimized. In such a scenario, the AT uses the monitoring credits to determine whether to monitor control channels of a non-serving sector to determine whether the DRC Lock for the non-serving sector is “in-lock.” Therefore, the monitoring credits for a non-serving sector (CM_NS) are incremented if: 
   the forward link SINR of the non-serving sector (FL_NS) is greater than the forward link SINR of the current serving sector (FL_SS) by a FL_SINR_Th; and 
   the filtered RPC mean for the non-serving sector (RL_NS) is above the RPC_Th; and 
   the filtered RPC mean for the current serving sector (RL_SS) is below the RPC_Th. 
   CM_NS are decremented if the above conditions are not satisfied. 
   The credits, initialized to zero in the Initialization phase, are accumulated during the Credit Accumulation phase. The credit accumulation phase, in accordance with one embodiment, is illustrated in  FIG. 5 . In step  502 , a variable count is set to one. The method continues in step  504 . 
   In step  504 , the variable count is tested against an active set size. If the variable count is greater than the active set size, the method continues in decision phase; 
   otherwise, the method continues in step  506 . 
   In step  506 , the inquiry is made whether a sector designated by the variable count is the current serving sector. If the test is positive, the method continues in step  518 ; otherwise, the method continues in step  508 . 
   In step  508 , a forward link SINR of a sector designated by the variable count is compared against forward link SINR of the current serving sector modified by the FL_SINR_Th. If the forward link SINR of the sector designated by the variable count is greater than the forward link SINR of the current serving sector modified by the FL_SINR_Th, the method continues in step  510 ; otherwise, the method continues in step  512 . 
   In step  510 , a reverse link filtered RPC mean of the sector designated by the variable count is compared against the RPC_Th. If the reverse link filtered RPC mean of the sector designated by the variable count is greater than the RPC_Th, the method continues in step  511 ; otherwise, the method continues in step  516 . 
   In step  511 , a reverse link filtered RPC mean for the current serving sector is compared against the RPC_Th. If the reverse link filtered RPC mean for the current serving sector is greater than the RPC_Th, the method continues in step  512 ; otherwise, the method continues in step  514 . 
   In step  512 , values of CS_NS and CM_NS identified by the variable count are decremented by one, and set to the maximum of 0 and the decremented value. The method continues in step  518 . 
   In step  514 , the values of CS_NS and CM_NS identified by the variable count are incremented by one and set to the minimum of the soft (or softer) handoff delay (NS_S_Th) and the incremented value. The method continues in step  518 . 
   In step  516 , the value of CS_NS identified by the variable count is incremented by one, and set to the minimum of the soft (or softer) handoff delay (NS_S_Th) and the decremented value. The method continues in step  518 . 
   In step  518 , the variable count is incremented by one and the method returns to step  504 . 
   Decision 
   In one embodiment, the re-pointing decision rules depend on the DRC Lock Bit of the current serving sector. Consequently, referring to  FIG. 6 , in step  602 , a DRC Lock Bit of the current serving sector is tested. If the DRC Lock Bit of the current serving sector is “out-of-lock,” the method continues in step  604 ; otherwise, the method continues in step  606 . 
   In step  604 , the “out-of-lock” server selection method is initialized. The method is described in detail with reference to  FIG. 9 . The method returns to the credit accumulation phase. 
   In step  606 , the “in-lock” server selection method is initialized. The method is described in detail with reference to  FIGS. 7 and 8 . The method returns to the credit accumulation phase. 
   “In-Lock” Server Selection 
   If the DRC Lock Bit from the current serving sector is “in-lock”, the decision to re-point to a non-serving sector is made if the non-serving sector provides higher FL_SINR and an “in-lock” DRC Lock Bit. To carry out the decision, the AT first ascertains if any of the non-serving sectors has switching credits greater than a threshold determined by the soft/softer delay. (This, threshold is the same for both the switching and monitoring credits.) If at least one of the non-serving sectors has switching credits greater than the threshold, the AT re-points its DRC to the sector with the highest switching credits. In one embodiment, if two or more non-serving sectors have equal switching credits, the sector with the highest quality reverse link is selected. The quality of the reverse link is determined in accordance with the filtered RPC mean. Lower filtered RPC mean indicates a better quality of the reverse link. In another embodiment, if two or more non-serving sectors have equal switching credits, the sector with the highest quality forward link is selected. 
   If none of the non-serving sectors has sufficient switching credits to mandate re-pointing, the AT ascertains how many of the non-serving sectors have monitoring credits greater than the threshold. If at least one of the non-serving sectors has monitoring credits greater than the threshold, the AT monitors the control channel from those non-serving sectors during the next control channel cycle. In one embodiment, if two or more non-serving sectors have equal switching credits, a sector with the highest quality reverse link is selected for the monitoring. The quality of the reverse link is determined in accordance with the filtered RPC mean. In another embodiment, if two or more non-serving sectors have equal switching credits, a sector with the highest quality forward link is selected for the monitoring. If the DRC for the monitored sector is “in-lock,” the AT re-points to the monitored sector. Following the re-pointing the AT resets all the switching and monitoring credits. 
   If none of the non-serving sectors has either sufficient switching credits or monitoring credits, the AT continues pointing its DRC to the current serving Access Point. 
   The decision phase in accordance with one embodiment is illustrated in  FIGS. 7 and 8 . In accordance with  FIG. 7 , a non-serving sector is made a candidate for re-pointing if the non-serving sector&#39;s switching credits are equal to the soft (or softer) handoff delay (NS_S_Th) for the non-serving sector. A non-serving sector is made a candidate for a control channel monitoring if the non-serving sector&#39;s monitoring credits are equal to the soft (or softer) handoff delay (NS_S_Th) for the non-serving sector and the filtered RPC mean of the non-serving sector is above RPC_Th. This ensures that the AT is in reliable communication with the current serving sector when it attempts to demodulate the synchronous control channel from a non-serving sector. These two requirements ensure that the DRC from the non-serving sector is “in-lock” with a probability PIL. 
   Furthermore, in one embodiment, a data packet may span two control channel cycles and, consequently, the data transmission from the current serving sector may collide with the control channel transmission from the sector to be monitored. 
   Consequently, the AT further determines whether there is potential for a collision between the data on the control channel to be monitored and the data form the current serving sector. If the AT determines that the data transmission from the current serving sector would collide with the transmission of the control channel from the non-serving sector to be monitored, then the AT does not monitor the control channel from the non-serving sector. Otherwise, the AT would monitor the control channel from the non-serving sector. 
   In step  702 , a variable count is set to one. The method continues in step  704 . 
   In step  704 , the variable count is tested against an active set size. If the variable count is greater than the active set size, the method continues in server selection of  FIG. 8 ; otherwise, the method continues in step  706 . 
   In step  706 , an inquiry is made whether a sector designated by the variable count is the current serving sector. If the test is positive, the method continues in step  724 ; otherwise, the method continues in step  708 . 
   In step  708 , a value of the variable CS_SS identified by the variable count is compared against the soft (or softer) handoff delay (NS_S_Th) for the non-serving sector. If the value of the variable CS_SS is not equal to the NS_S_Th, the method continues in step  710 ; otherwise, the method continues in step  712 . 
   In step  710 , a value of the variable Cand_S identified by the variable count is set to 0. The method continues in step  714 . 
   In step  712 , a value of the variable Cand_S identified by the variable count is set to 1. The method continues in step  714 . 
   In step  714 , a value of the variable CM_NS identified by the variable count is compared against the soft (or softer) handoff delay (NS_S_Th) for the non-serving sector. If the value of the variable CM_NS is not equal to the NS_S_Th for the non-serving sector, the method continues in step  716 ; otherwise, the method continues in step  720 . 
   In step  716 , the filtered RPC mean of the current serving sector (RPC_CS) identified by the variable count is compared against an RPC threshold (RPC_Th). If the RPC_CS is less than the RPC_Th, the method continues in step  718 ; otherwise, the method continues in step  720 . 
   In step  718 , the AT determines whether the data on the control channel to be monitored and the data from the current serving sector collide. If the AT determines that the data transmission from the current serving sector would collide with the transmission of the control channel from the non serving sector to be monitored, then the method continues in step  720 . Otherwise, the method continues in step  722 . 
   In step  720 , a value of the variable Cand_M identified by the variable count is set to 0. The method continues in step  724 . 
   In step  722 , a value of the variable Cand_M identified by the variable count is set to 1. The method continues in step  724 . 
   In step  724 , the variable count is incremented, and the method returns to step  704 . 
   Referring to  FIG. 8 , the “in-lock” selection from  FIG. 7  continues. In accordance with  FIG. 8 , the AT ascertains which sectors are candidates for re-pointing and/or monitoring, and carries out the re-pointing decision. 
   In step  802 , where a variable count is set to one, the method continues in step  804 , in which the variable count is tested against an active set size. If the variable count is greater than the active set size, the method continues in step  814 ; otherwise, the method continues in step  806 . 
   In step  806 , an inquiry is made whether the sector designated by the variable count is the current serving sector. If the test is positive, the method continues in step  812 ; otherwise, the method continues in step  808 . 
   In step  808 , a variable Cand_S identified by the variable count is compared to one. If the variable Cand_S identified by the variable count is equal to one, the method continues in step  810 ; otherwise the method continues in step  812 . 
   In step  810 , a variable CS_NS_count is incremented by one. The method continues in step  812 . 
   In step  812 , the variable count is incremented, and the method returns to step  804 . 
   In step  814 , the value of the variable CS_NS_count is ascertained. If the value of the variable CS_NS_count is equal to 1, the method continues in step  816 . If the value of the variable CS_NS_count is greater that 1, the method continues in step  818 . Otherwise, the method continues in step  822 . 
   In step  816 , the AT re-points the DRC to the candidate sector identified by the variable count. The method continues in step  820 . 
   In step  818 , the AT re-points the DRC to the candidate sector identified by the variable count that has the highest quality reverse link in accordance with the sector&#39;s reverse link&#39;s filtered RPC mean. The method continues in step  820 . 
   In step  820 , the variables CS_NS and the variables CM_NS are set to zero. The method returns to the credit accumulation phase. 
   In step  822 , a variable count is set to one. The method continues in step  824 . 
   In step  824 , the variable count is tested against an active set size. If the variable count is greater than the active set size, the method continues in step  834 ; otherwise, the method continues in step  826 . 
   In step  826 , an inquiry is made whether the sector designated by the variable count is the current serving sector. If the test is positive, the method continues in step  832 ; otherwise, the method continues in step  828 . 
   In step  828 , a variable Cand_M identified by the variable count is compared to one. If the variable Cand_M identified by the variable count is equal to one, the method continues in step  830 ; otherwise the method continues in step  832 . 
   In step  830 , a variable CM_NS_count is incremented. The method continues in step  832 . 
   In step  832 , the variable count is incremented, and the method returns to step  824 . 
   In step  834 , the value of the variable CM_NS_count is ascertained. If the value of the variable CM_NS_count is equal to 1, the method continues in step  836 . If the value of the variable CM_NS_count is greater that 1, the method continues in step  838 . If the value of the variable CM_NS_count is equal to 0, the method continues in step  840 . 
   In step  836 , the AT monitors the DRC from the candidate sector identified by the variable count. The method continues in step  842 . 
   In step  838 , the AT monitors the DRC from the candidate sector identified by the variable count that has the highest quality reverse link in accordance with the AP&#39;s reverse link&#39;s filtered RPC mean. The method continues in step  842 . 
   In step  840 , the AT makes the-decision not to re-point to a different sector. The method returns to credit accumulation. 
   In step  842 , the DRC from the candidate sector is evaluated. If the DRC value is “in lock,” the method continues in step  844 ; otherwise, the method returns to credit accumulation. 
   In step  844 , the AT re-points the DRC to the candidate sector. The method continues in step  846 . 
   In step  846 , the variables CS_NS and the variables CM_NS are set to zero. The method returns to credit accumulation. 
   “Out-of-Lock” Server Selection 
   If the DRC from the current serving sector is “out-of-lock,” the decision to re-point to a non-serving sector is made if the non-serving sector provides higher FL_SINR and better quality reverse link, as determined by the switching credits. To carry out the decision, the AT first ascertains those non-serving sectors that have switching credits greater than zero. If at least one of the non-serving sectors has switching credits greater than zero, the AT re-points the DRC to the sector with the highest switching credits. In one embodiment, if two or more non-serving sectors have equal switching credits, a sector with the highest quality reverse link is selected. The quality of the reverse link is determined in accordance with the reverse link&#39;s filtered RPC mean. In another embodiment, if two or more non-serving sectors have equal switching credits, a sector with the highest quality forward link is selected. 
   If none of the non-serving sectors has switching credits greater than zero, the AT ascertains those non-serving sectors that have monitoring credits greater than zero. If at least one of the non-serving sectors has monitoring credits greater than zero, the AT monitors the sector with the highest monitoring credits. In one embodiment, if two or more non-serving sectors have equal monitoring credits, the sector with the highest quality reverse link is selected for the monitoring. The quality of the reverse link is determined in accordance with the filtered RPC mean. In another embodiment, if two or more non-serving sectors have equal monitoring credits, the sector with the highest quality forward link is selected for the monitoring. If the DRC for the monitored sector is “in-lock,” the AT re-points to the monitored sector. On re-pointing the DRC the AT resets all the switching and re-pointing credits. 
   If none of the non-serving sectors has either sufficient switching credits or monitoring credits, the AT continues pointing its DRC to the current serving sector. 
   The “out-of-lock” sector selection in accordance with one embodiment is illustrated in  FIG. 9 . In step  902 , a variable CS_NS_COUNT is set to zero. The method continues in step  904 . 
   In step  904 , the variable count is set to one. The method continues in step  906 . 
   In step  906 , the variable count is tested against an active set size. If the variable count is greater than the active set size, the method continues in step  916 ; otherwise, the method continues in step  908 . 
   In step  908 , an inquiry is made whether the sector designated by the variable count is the current serving sector. If the test is positive, the method continues in step  910 ; otherwise, the method continues in step  914 . 
   In step  910 , a variable CS_NS identified by the variable count is compared to zero. If the variable CS_NS identified by the variable count is equal to zero, the method continues in step  912 ; otherwise the method continues in step  914 . 
   In step  912 , a variable CS_NS_count is incremented. The method continues in step  914 . 
   In step  914 , the variable count is incremented, and the method returns to step  906 . 
   In step  916 , the value of the variable CS_NS_count is ascertained. If the value of the variable CS_NS_count is equal to 1, the method continues in step  918 . If the value of the variable CS_NS_count is greater that 1, the method continues in step  920 . Otherwise, the method continues in step  922 . 
   In step  918 , the AT re-points the DRC to the candidate sector identified by the variable count. The method continues in step  944 . 
   In step  920 , the AT re-points the DRC to the candidate sector identified by the variable count that has the highest quality reverse link in accordance with the AP&#39;s reverse link&#39;s filtered RPC mean. The method continues in step  944 . 
   In step  922 , a variable CM_NS_count is set to zero. The method continues in step  924 . 
   In step  924 , a variable count is set to one. The method continues in step  926 . 
   In step  926 , the variable count is tested against an active set size. If the variable count is greater than the active set size, the method continues in step  936 , otherwise, the method continues in step  928 . 
   In step  928 , an inquiry is made whether the sector designated by the variable count is the current serving sector. If the test is negative, the method continues in step  934 ; otherwise, the method continues in step  930 . 
   In step  930 , a variable CM_NS identified by the variable count is compared to zero. If the variable CM_NS identified by the variable count is less than zero, the method continues in step  934 ; otherwise the method continues in step  932 . 
   In step  932 , a variable CM_NS_count is incremented. The method continues in step  934 . 
   In step  934 , the variable count is incremented, and the method returns to step  924 . 
   In step  936 , the value of the variable CM_NS_count is ascertained. If the value of the variable CM_NS_count is equal to 1, the method continues in step  938 . If the value of the variable CM_NS_count is greater that 1, the method continues in step  940 . If the value of the variable CM_NS_count is equal to 0, the method continues in step  942 . 
   In step  938 , the AT re-points the DRC to the candidate sector identified by the variable count. The method continues in step  944 . 
   In step  940 , the AT re-points the DRC to the candidate sector identified by the variable count that has the highest quality reverse link in accordance with the AP&#39;s reverse link&#39;s filtered RPC mean. The method continues in step  944 . 
   In step  942 , the AT makes the decision not to re-point to a different sector. The method returns to credit accumulation. 
   Access Terminal Processing 
   In another embodiment, the AT is assumed to be able to demodulate a control channel from each sector in the AT&#39;s active set. The processing method at the AT in accordance with the embodiment comprises the phases of (i) Initialization, (ii) Credit Accumulation, and (iii) Decision. 
   Initialization 
   During the initialization stage, the AT  104  selects the AP with the best forward link quality metric, i.e., the highest SINR. The AT  104  sets the DRC “in-lock,” for the selected AP. The AT  104  then initializes credits for all non-serving sectors to zero. 
   Because the AT is able to demodulate a control channel from each sector in the AT&#39;s active set, thus determining the DRC Lock Bit value, there is no need for monitoring credits and only switching credits are defined. The switching credits are described in more details in the Credit Accumulation paragraph. Consequently, the initialization phase in accordance with the embodiment is carried out according to  FIG. 4  and the accompanying text, except for step  412 . In step  412 , only the switching credits for a non-serving sector (CS_NS) are set to zero. 
   Credit Accumulation 
   As discussed, only switching credits are required in accordance with the embodiment. Switching credits are used to qualify the non-serving sector for re-pointing if the DRC of the non-serving sector is “in lock.” Consequently, CS_NS are incremented if: 
   a forward link SINR of the non-serving sector (FL_NS) is greater than a forward link SINR of the current serving sector by a pre-determined value (FL_SINR_Th); and 
   a DRC Lock Bit of the non-serving sector is “in-lock.” 
   The pre-determined value FL_SINR_Th is selected so that re-pointing to a new sector results in an increase in forward link SINR and, consequently, in an increase in an average requested data rate. CS_NS are decremented if the above conditions are not satisfied. 
   In one embodiment, the switching credits minimum value is zero and the maximum value is equal to a soft handoff delay if re-pointing to the particular sector would constitute a soft handoff, or a softer handoff delay if re-pointing to the particular AP would constitute a softer handoff. 
   The credits, initialized to zero in the Initialization phase are accumulated during the Credit Accumulation phase. The credit accumulation phase in accordance with one embodiment is illustrated in  FIG. 10 . In step  1002 , a variable count is set to one. The method continues in step  1004 . 
   In step  1004 , the variable count is tested against an active set size. If the variable count is greater than the active set size, the method continues in decision phase; otherwise, the method continues in step  1006 . 
   In step  1006 , the inquiry is made whether the sector designated by the variable count is the current serving sector. If the test is positive, the method continues in step  1016 ; otherwise, the method continues in step  1008 . 
   In step  1008 , a forward link SINR of the sector designated by the variable count is compared against forward link SINR of the current serving sector modified by the FL_SINR_Th. If the forward link SINR of the sector designated by the variable count is greater than the forward link SINR of the current serving sector modified by the FL_SINR_Th, the method continues in step  1010 ; otherwise, the method continues in step  1012 . 
   In step  1010 , a DRC Lock Bit of the sector designated by the variable count is compared against one. If the DRC Lock Bit of the sector designated by the variable count is equal to one, the method continues in step  1014 ; otherwise, the method continues in step  1012 . 
   In step  1012 , the value of CS_NS identified by the variable count is decremented by one and set to the maximum of 0 and the decremented value. The method continues in step  1016 . 
   In step  1014 , the value of CS_NS identified by the variable count are incremented by one and set to the minimum of the soft (or softer) handoff delay and the incremented value. The method continues in step  1016 . 
   In step  1016 , the variable count is incremented by one and the method returns to step  1004 . 
   Decision 
   In accordance with the embodiment, the re-pointing decision rules depend on the DRC Lock State of the current serving sector. Consequently, the decision phase in accordance with the embodiment is carried out according to  FIG. 6  and accompanying text. 
   “In-Lock” AP Selection 
   If the DRC from the current serving sector is “in-lock,” the decision to re-point to a non-serving sector is made if the non-serving sector provides higher FL_SINR and an “in-lock” DRC. To carry out the decision, the AT first ascertains if any of the non-serving sectors has switching credits greater than a threshold determined by the soft/softer delay. If at least one of the non-serving sectors has switching credits greater than the threshold, the AT re-points its DRC to the AP with the highest switching credits. In one embodiment, if two or more non-serving sectors have equal switching credits, a sector with the highest quality reverse link is selected. The quality of the reverse link is determined in accordance with the filtered RPC mean. In another embodiment, if two or more non-serving sectors have equal switching credits, a sector with the highest quality forward link is selected. 
   To avoid limiting the re-pointing rate to a control channel interval (256 time-time-slots for IS-856), a non-serving sector is further made a candidate for re-pointing between control channel intervals according to the following rules: 
   the number of time-slots since the last control channel (CC) exceeds a threshold N c ; and 
   the filtered RPC mean for the non-serving sector (RL_NS) is less than the RPC_Th. 
   The RPC_Th is chosen such that the DRC for the non-serving sector is “in-lock” with a probability PIL if the filtered RPC mean is below RPC_Th. In one embodiment, the Nc is equal to 64. 
   If none of the non-serving sectors has sufficient switching credits, the AT continues pointing its DRC to the current serving sector. On re-pointing the DRC the AT resets all the switching credits. 
   The candidate determination in accordance with the embodiment is illustrated in  FIG. 11 . In step  1102 , a variable count is set to one. The method continues in step  1104 . 
   In step  1104 , the variable count is tested against an active set size. If the variable count is greater than the active set size, the method continues in server selection as described below; otherwise, the method continues in step  1106 . 
   In step  1106 , an inquiry is made whether the sector designated by the variable count is the current serving sector. If the test is positive, the method continues in step  1118 ; otherwise, the method continues in step  1108 . 
   In step  1108 , a value of the variable CS_NS identified by the variable count is compared against the soft (or softer) handoff delay (NS_S_Th) for the non-serving sector. If the value of the variable CS_NS is not equal to the NS_S_Th for the non-serving sector, the method continues in step  1110 ; otherwise, the method continues in step  1112 . 
   In step  1110 , a value of the variable identifying the number of time-slots since the last control channel (CC) is compared against the NC. If the CC is greater than the Nc, the method continues in step  1114 ; otherwise, the method continues in step  1116 . 
   In step  1112 , a value of the variable Cand_S identified by the variable count is set to zero. The method continues in step  1118 . 
   In step  1114 , a filtered RPC mean of the non-serving sector (RL_NS) identified by the variable count is compared against an RPC threshold (RPC_Th). If the RL_NS is greater than the RPC_TH, the method continues in step  1112 ; otherwise, the method continues in step  1116 . 
   In step  1116 , a value of the variable Cand_S identified by the variable count is set to one. The method continues in step  1118 . 
   In step  1118 , the variable count is incremented, and the method returns to step  1104 . 
   In accordance with the decision rules, the AT ascertains which sectors are candidates for re-pointing, and carries out the re-pointing decision. The decision phase in accordance with the embodiment is carried out according to  FIG. 9  and the accompanying text, with the following modifications. Because the embodiment does not use the monitoring credits, steps  922  through  946  are deleted. Consequently, in step  914 , if the value of the variable CS_NS_count is equal to zero, the method continues pointing to the current serving Access Point, and then returns to the Credit Accumulation phase. 
   “Out-of-Lock” AP Selection 
   If the DRC from the current serving sector is “out-of-lock” the decision to re-point to a non-serving sector is made if the non-serving sector provides higher FL_SINR and better quality reverse link, as determined by the switching credits. To carry out the decision, the AT first ascertains those non-serving sectors that have switching credits greater than zero. If at least one of the non-serving sectors has switching credits greater than zero, the AT re-points its DRC to the sector with the highest switching credits. In one embodiment, if two or more non-serving sectors have equal switching credits, a sector with the highest quality reverse link is selected. The quality of the reverse link is determined in accordance with the reverse link&#39;s filtered RPC mean. In another embodiment, if two or more non-serving sectors have equal switching credits, a sector with the highest quality forward link is selected. 
   If none of the non-serving sectors has sufficient switching credits, the AT continues pointing its DRC to the current serving Access Point. 
   The decision phase in accordance with the embodiment is carried out according to  FIG. 9  and the accompanying text, with the following modifications. Because the embodiment does not use the monitoring credits, steps  922  through  946  are deleted. Consequently, in step  914 , if the value of the variable CS_NS_count is equal to zero, the method continues pointing to the current serving Access Point, and then returns to the Credit Accumulation phase. 
   Further Extension 
   One skilled in the art recognizes that the concepts explained in the two above-described embodiments can be utilized to devise a hybrid method in which the AT would be able to demodulate a control channel from at least two sectors in the AT&#39;s active set. A modification to a Credit Accumulation phase as required in one embodiment is illustrated in  FIG. 12 . All other phases do not require any modifications. 
   In step  1210 , the sectors control channels to be demodulated are determined. In one embodiment, the determination is carried out in accordance with the sector&#39;s filtered forward link SINR. Sectors are sorted based on their filtered forward link SINR. Then the AT selects the number of sectors it is able to demodulate as the sectors with the highest SINR. 
   In step  1212 , a variable count is set to one. The method continues in step  1214 . 
   In step  1214 , the variable count is tested against an active set size. If the variable count is greater than the active set size, the method continues in decision phase; 
   otherwise, the method continues in step  1216 . 
   In step  1216 , the inquiry is made whether a sector designated by the variable count is the current serving sector. If the test is positive, the method continues in step  1236 ; otherwise, the method continues in step  1218 . 
   In step  1218 , a forward link SINR of a sector designated by the variable count is compared against forward link SINR of the current serving sector modified by the FL_SINR_Th. If the forward link SINR of the sector designated by the variable count is greater than the forward link SINR of the current serving sector modified by the FL_SINR_Th, the method continues in step  1222 ; otherwise, the method continues in step  1220 . 
   In step  1220 , a test whether a sector identified by the variable count was selected for demodulating is performed. If the test is negative, the method continues in step  1228 ; otherwise the method continues in step  1234 . 
   In step  1222 , a test whether a sector identified by the variable count was selected for demodulating is performed. If the test is negative, the method continues in step  1224 ; otherwise the method continues in step  1226 . 
   In step  1224 , a reverse link filtered RPC mean of the sector designated by the variable count is compared against the RPC_Th. If the reverse link filtered RPC mean of the sector designated by the variable count is greater than the RPC_Th, the method continues in step  1225 ; otherwise, the method continues in step  1232 . 
   In step  1225 , a reverse link filtered RPC mean for the current serving sector is compared against the RPC_Th. If the reverse link filtered RPC mean for the current serving sector is greater than the RPC_Th, the method continues in step  1228 ; otherwise, the method continues in step  1230 . 
   In step  1226 , a DRC Lock of the sector identified by the variable count is compared to one. If the DRC Lock of the sector identified by the variable count is equal to one, the method continues in step  1232 ; otherwise the method continues in step  1234 . 
   In step  1228 , values of CS_NS and CM_NS identified by the variable count are decremented by one, and set to the maximum of 0 and the decremented value. The method continues in step  1236 . 
   In step  1230 , the values of CS_NS and CM_NS identified by the variable count are incremented by one, and set to the minimum of the soft (or softer) handoff delay (NS_S_Th) and the incremented value. The method continues in step  1236 . 
   In step  1232 , the value of CS_NS identified by the variable count is incremented by one and set to the minimum of the soft (or softer) handoff delay (NS_S_Th) and the decremented value. The method continues in step  1236 . 
   In step  1234 , the value of CS_NS identified by the variable count is decremented by one, and set to the maximum of 0 and the decremented value. The method continues in step  1236 . 
   In step  1236 , the variable count is incremented by one and the method returns to step  1214 . 
   Re-Pointing Using a Punctured DRC Lock 
   Depending on an implementation of a communication system, a performance of the re-pointing method using a DRC Lock for indication of a reverse link condition may suffer due to the delay in the feedback loop. The update rate of the feedback loop may be too slow in handling sudden changes in reverse link quality. Such performance detriment may result in outages, which may be intolerable in certain application, e.g., real-time applications. 
   Therefore, in another embodiment, the DRC Lock Bit is updated at a higher rate and punctured into an RPC channel one or more times every frame. The term punctured is used herein to mean sending the DRC Lock Bit instead of a RPC bit. The DRC Lock Bit is sent by all the AP&#39;s in the AT  104  active set. In one embodiment, a transmission of the DRC Lock Bit to each AT is staggered, i.e., referenced off a frame offset assigned to the AT. This allows for allocating additional power to the RPC channel during the transmission of the DRC Lock Bit in order to provide an additional margin to reduce the DRC Lock Bit errors at the AT; therefore, preventing an erroneous handoffs and possible loss in forward link throughput. The AT  104  uses the DRC Lock Bit information to select the serving AP. 
   Access Point Processing 
   The method in accordance with one embodiment is illustrated in  FIG. 13 . The method starts in step  1302 . The method continues in step  1304 . 
   In step  1304 , the AP receives an updated DRC. The method continues in step  1306 . 
   In step  1306 , the AP tests the received DRC. If the DRC was erased, the method continues in step  1308 ; otherwise, the method continues in step  1310 . 
   In step  1308 , the DRC erasure is assigned a value of 1. The method continues in step  1312 . 
   In step  1310 , the DRC erasure is assigned a value of 0. The method continues in step  1312 . 
   In step  1312 , the DRC Erasure Bit is processed to generate a DRC erasure rate. In one embodiment, the processing comprises filtering by a filter with a pre-determined time constant. In one embodiment, the filter is realized in a digital domain. The value of the pre-determined time constant is established in accordance with system simulation, by experiment or other engineering methods known to one of ordinary skills in the art as an optimum in accordance with: 
   reliability of an estimate ensuing from a choice of the time constant; and 
   latency of an estimate ensuing from a choice of the time constant. 
   In one embodiment, pre-determined time constant is 64 time-slots. The method continues in step  1314 . 
   In step  1314 , the system time is tested to establish whether the DRC Lock Bit is to be punctured into the RPC sub channel. In one embodiment, illustrated in step  1314 , the DRC Lock Bit is punctured into the RPC sub channel each eighth (mod 8) time instance. Because the aim of selecting the time instance is to achieve a pre determined bit error rate, one of ordinary skills in the art recognizes that other time instances can be selected. The values of the time instance is selected to optimize the following requirements: 
   Minimize the degradation of the reverse link resulting from loss of RPC bits due to puncturing; and
         providing the DRC Lock Bit at optimal spacing.       

   If the test is positive, the method continues in step  1330 ; otherwise the method continues in step  1316 . 
   In step  1316 , the system time is tested to establish whether the DRC Lock Bit is to be updated. The time instance for the update is selected to ensure reliable delivery of the DRC Lock Bit. In one embodiment, illustrated in step  1316 , the DRC Lock Bit is updated every sixty-fourth (mod 64) time instance. If the test is positive, the method continues in step  1318 ; otherwise the method returns to step  1304 . 
   Steps  1318  through  1328  introduce hysteresis rules for generating the DRC Lock Bit. The hysteresis is introduced to avoid rapid re-pointing when the channel SINR varies rapidly. The hysteresis rules are as follows: 
   If the DRC Lock Bit is currently set to one, then the filtered DRC erasure rate must exceed first DRC erasure threshold (DRC-Erasure_Th2) for the DRC Lock Bit to be set to zero; and
         if the DRC Lock Bit is currently set to zero, then the Filtered DRC Erasure rate has to be below a second pre-determined DRC erasure threshold (DRC_Erasure_Th1) for the DRC Lock to be set to one.       

   In one embodiment, the values DRC_Erasure_Th1 and DRC_Erasure_Th2 are pre-determined in accordance with the communication system simulation by experiment or other engineering methods known to one of ordinary skills in the art. In another embodiment, the values DRC_Erasure_Th1 and DRC_Erasure_Th2 are changed in accordance with the change of the conditions of the communication link. In either embodiment, the values of DRC_Erasure_Th1 and DRC_Erasure_Th2 are selected to optimize the following requirements:
         minimize the dead-zone (when the DRC Lock Bit is not updated); and   transmit the most current reverse link channel state information to the AT.       

   In step  1318 , the DRC Lock Bit value is compared to 1. If the DRC Lock Bit value equals 1, the method continues in step  1322 ; otherwise, the method continues in step  1320 . 
   In step  1320 , the DRC erasure rate is compared to the DRC_Erasure_Th1. If the DRC erasure rate is greater than the DRC_Erasure_Th1, the method continues in step  1324 ; otherwise, the method continues in step  1326 . 
   In step  1322 , the DRC erasure rate is compared to the DRC_Erasure_Th2. If the DRC erasure rate is less than the DRC_Erasure_Th2, the method continues in step  1326 ; otherwise, the method continues in step  1328 . 
   In step  1324 , the DRC Lock Bit value is set to 0. The method continues in step  1330 . 
   In step  1326 , the DRC Lock Bit value is set to 1. The method continues in step  1330 . 
   In step  1328 , the DRC Lock Bit value is set to 0. The method continues in step  1330 . 
   In step  1330 , the DRC Lock Bit is punctured into the RPC channel in accordance with the timing signal obtained in step  1314 . The method returns to step  1306 . 
   Access Terminal Processing 
   The AT  104  receives and demodulates the RPC channel from all APs in the AT  104  active set. Consequently, the AT  104  recovers the DRC Lock Bits punctured into the RPC channel for every AP in the AT  104  active set. Furthermore, as discussed, the punctured DRC Lock Bits are updated with a higher frequency than the Message Based DRC Lock Bits. Consequently, in a Demodulation phase, the AT  104  can combine the energy of received DRC Lock Bits during one update interval, and compare the combined DRC Lock Bits energy against a DRC Lock Bit threshold. If the combined DRC Lock Bit energy is greater than the DRC Lock Bit threshold, the AT  104  declares the DRC Lock Bit from the particular AP “in-lock.” In the Decision phase, the AT  104  uses the DRC Lock Bit value to make a re-pointing decision. 
   Demodulation Phase 
   The Demodulation phase in accordance with one embodiment is illustrated in  FIG. 14 . The method starts in step  1402  and continues in step  1404 . 
   In step  1404 , the system time is tested to establish whether the DRC Lock Bit was updated. In one embodiment, illustrated in step  1404 , the DRC Lock Bit is updated every sixty-fourth (mod 64) time instance. This time instance corresponds to the update rate at the AP. If the test is positive, the method continues in step  1410 ; otherwise the method returns to step  1406 . 
   In step  1406 , the system time is tested to establish whether the DRC Lock Bit was punctured into the RPC sub channel. In one embodiment, illustrated in step  1404 , the DRC Lock Bit is punctured into the RPC sub channel each eighth (mod 8) time instance. This time instance corresponds to the puncture rate at the AP. If the test is positive, the method continues in step  1408 ; otherwise the method returns to step  1404 . 
   In step  1410 , the combined DRC Lock Bit energy is tested against a DRC Lock Bit threshold (DRC_LB_TH). If the test is positive, the method continues in step  1412 ; 
   otherwise the method returns to step  1414 . 
   In step  1412 , the DRC Lock Bit value is set to 1. The method continues in step  1416 . 
   In step  1414 , the DRC Lock Bit value is set to 0. The method continues in step  1416 . 
   In step  1416 , the variable containing the combined DRC Lock Bit energy is set to zero for the next update. 
   Decision Phase 
   The AT uses the DRC Lock Bit value obtainer in the Demodulation phase to make a decision with respect to a re-pointing. In one embodiment, the decision phase comprises (i) Accreditation phase, (ii) Certification phase, and (iii) Decision phase. The respective phases are described below. 
   Accreditation Phase 
   In the accreditation phase, the forward link SINR of the non-serving sectors (FL_NS) is compared to the forward link SINR of the current serving sector modified by a pre-determined hysteresis margin (FL_HYST). If the forward link SINR of the non-serving sector is greater than the forward link SINR of the serving sector modified by a pre-determined hysteresis margin, then the temporary credits (TEMP_CREDIT) associated with that non-serving sector are incremented; otherwise, the temporary credits associated with that non-serving sector are decremented. 
   The Accreditation phase in accordance with one embodiment is illustrated in  FIG. 15 . The method starts in step  1502 . The method continues in step  1504 . 
   In step  1504 , a variable count is set to zero. The method continues in step  1506 . 
   In step  1506 , the variable count is tested against an active set size. If the variable count is greater than the active set size, the method continues in the Certification phase; otherwise, the method continues in step  1508 . 
   In step  1508 , an inquiry is made whether the forward link SIR of the sector designated by the variable count is greater than the forward link SINR of the current serving sector modified by a pre-determined hysteresis margin. If the test is positive, the method continues in step  1512 ; otherwise, the method continues in step  1510 . 
   In step  1510 , the temporary credits for the sector identified by the variable count are decreased by one. The method continues in step  1514 . 
   In step  1512 , the temporary credits for the sector identified by the variable count are increased by one. The method continues in step  1514 . 
   In step  1514 , the variable count is increased by one. The method returns to step  1506 . 
   Certification Phase 
   In the certification phase, the credits of the sectors are certified. The term certification as used herein means a decision, which sectors&#39; credits (CREDITS) will be increased by the temporary credits accumulated by the sector during the accreditation phase. In one embodiment, the certification decision is made in accordance with the following rules: 
   If the DRC Lock Bit of the current serving sector is “in-lock,” and if the DRC Lock Bit on a non-serving sector is “in-lock,” then the credits of the non-serving sector are incremented by the DRC Lock Interval. The term DRC Lock interval as used herein means a number of time-slots over which the DRC Lock Indication has been sent; 
   if the DRC Lock Bit of the current serving sector is “out-of-lock”, and if the DRC Lock Bit on a non-serving sector is “in-lock” then the credits of the non-serving sector are incremented by the number of accumulated temporary credits; 
   otherwise the credits of the non-serving sector are set to zero. 
   The Certification phase in accordance with one embodiment is illustrated in  FIG. 16 . The method starts in step  1602 , in which a variable count is set to zero. The method continues in step  1604 . 
   In step  1604 , the variable count is tested against an active set size. If the variable count is greater than the active set size, the method continues in the Decision phase; otherwise, the method continues in step  1606 . 
   In step  1606 , the DRC_LOCK of the serving sector is compared to 1. If the DRC_LOCK is equal to 1, the method continues in step  1610 ; otherwise, the method continues in step  1608 . 
   In step  1608 , the DRC_LOCK of the non-serving sector identified by the variable count is compared to 1. If the DRC_LOCK is equal to 1, the method continues in step  1612 ; otherwise, the method continues in step  1614 . 
   In step  1612 , the credits of the non-serving sector identified by the variable count is set to the value of temporary credits. 
   In step  1614 , the credits of the non-serving sector identified by the variable count are set to 0. 
   In step  1610 , the DRC_LOCK of the non-serving sector identified by the variable count is compared to 1. If the DRC_LOCK is equal to 1, the method continues in step  1616 ; otherwise, the method continues in step  1614 . 
   In step  1616 , the credits of the non-serving sector identified by the variable count is set to the value of DRC Lock Update Interval. 
   In step  1618 , the variable count is increased by one. The method returns to step  1604 . 
   Decision Phase 
   In the decision phase, the AT makes a re-pointing decision in accordance with the certified credits. In one embodiment, the AT determines the non-serving sectors, the certified credits of which are greater than or equal to the soft/softer handoff delay of the sector. The AT then re-points to one of the determined sectors that has the highest credits. If multiple sectors have equal credits, then the AT repoints the DRC to the sector with the best forward link. 
   The Decision phase in accordance with one embodiment is illustrated in  FIG. 17 . 
   The method starts in step  1702 , in which a variable count is set to zero. The method continues in step  1704 . 
   In step  1704 , the variable count is tested against an active set size. If the variable count is greater than the active set size, the method continues in step  1716 , otherwise, the method continues in step  1706 . 
   In step  1706 , the temporary credits of the sector identified by the variable count are compared to the soft (or softer) handoff delay for the non-serving sector (NS_S_Th) identified by the variable count. If the credits are less than the soft (or softer) handoff delay for the non-serving sector (NS_S_Th) identified by the variable count, the method continues in step  1710 ; otherwise, the method continues in step  1712 . 
   In step  1710 , the re-pointing flag is set to zero. The method continues in step  1714 . 
   In step  1712 , the re-pointing flag is set to one. The method continues in step  1714 . 
   In step  1714 , the variable count is incremented. The method returns to step  1704 . 
   In step  1716 , the sectors with a re-pointing flag set to 1 are sorted in accordance to the sectors&#39; accumulated credits. The method continues in step  1718 . 
   In step  1718 , a test is made whether two or more sectors have equal value of the accumulated credits. If the test is positive, the method continues in step  1720 ; otherwise the method continues in step  1722 . 
   In step  1720 , the AT re-points to the sector with the greatest value of a forward link SINR. The method continues in step  1724 . 
   In step  1722 , the AT re-points to the sector with the greatest value of the accumulated credit. The method continues in step  1724 . 
   In step  1724 , the accumulated credits of all sectors are initialized to zero. The method returns to the Demodulation phase. 
   Re-pointing Using Only Forward Link 
   In all previously described embodiments, the re-pointing decision was made by the AT  104  in accordance with a condition of both a forward and a reverse links. As discussed, the AT  104  can also make the re-pointing decision in accordance with a condition of a forward link or a condition on a reverse link. In accordance with another embodiment, the AT  104  makes the re-pointing decision in accordance with a condition of a forward link only. Because no feedback from a sector to an AT is provided, all processing is carried out at the AT. 
   Access Terminal Processing 
   The processing method at the AT in accordance with the embodiment comprises the phases of (i) Initialization, (ii) Credit Accumulation, and (iii) Decision, as described in reference to paragraph 1.2, and associated FIGS, modified as follows. 
   Initialization 
   During the initialization stage, the AT  104  selects a sector with the best forward link quality metric, i.e., the highest SINR, as the serving sector. The AT  104  sets the DRC for the selected sector “in-lock” and initializes credits for all non-serving sectors to zero. 
   In one embodiment, only one type of credits—switching credits—is defined. 
   Consequently, in  FIG. 4  and the accompanying text only the switching credits are initialized to zero in step  412 . 
   Credit Accumulation 
   The switching credits are used to qualify a non-serving sector for re-pointing. 
   The switching credits (CS_NS) are incremented if a forward link SINR of the non-serving sector (FL_NS) is greater than a forward link SINR of the current serving sector (FL_SS) modified by a pre-determined value (FL_SINR_Th). The CS_NS are decremented if the above condition is not satisfied. 
   The pre-determined value FL_SINR_Th is selected so that re-pointing to another sector results in an increase in forward link SINR and, consequently, in an increase in an average requested data rate. 
   In one embodiment, the minimum value for the credits is zero, and the maximum for the credits is equal to a soft handoff delay or a softer handoff delay. The delay used is determined based on whether or not the non-serving sector is in the same cell as the serving sector. If the non-serving sector is in the same cell as the serving sector then the softer handoff delay is used, and if the non-serving sector is in a cell different from the one that the serving sector is part of, then the soft handoff delay is used. 
   The credits, initialized to zero in the Initialization phase, are accumulated during the Credit Accumulation phase. Consequently, referring to  FIG. 5 , and the accompanying text, steps  510 ,  511 , and  514  are deleted. Furthermore, step  508  is modified as follows: 
   In step  508 , a forward link SINR of a sector designated by the variable count is compared against forward link SINR of the current serving sector modified by the FL_SINR_Th. If the forward link SINR of the sector designated by the variable count is greater than the forward link SINR of the current serving sector modified by the FL_SINR_Th, the method continues in step  516 ; otherwise, the method continues in step  512 . 
   Decision 
   Because no feedback information about the reverse link is presented to the AT, the sector selection is carried out in accordance with the switching credits. 
   To carry out the decision, the AT first ascertains if any of the non-serving sectors has switching credits greater than a threshold determined by the soft/softer delay (NS_S_Th) for the non-serving sector. (Thus, threshold is the same for both the switching and monitoring credits.) If at least one of the non-serving sectors has switching credits greater than the threshold, the AT re-points its DRC to the sector with the highest switching credits. If two or more non-serving sectors have equal switching credits, the sector with the highest current quality forward link is selected. 
   If none of the non-serving sectors has sufficient switching credits to mandate re-pointing, the AT continues pointing its DRC to the current serving Access Point. 
   The decision phase in accordance with one embodiment is illustrated in reference to  FIGS. 7 and 8  and the accompanying text. In reference with  FIG. 7 , steps  714  through  722  are deleted. Steps  710  and  712  are modified as follows: 
   In step  710 , a value of the variable Cand_S identified by the variable count is set to 0. The method continues in step  724 . 
   In step  712 , a value of the variable Cand_S identified by the variable count is set to 1. The method continues in step  724 . 
   Referring to  FIG. 8 , the sector selection from  FIG. 7  continues. In reference with  FIG. 8 , steps  822  through  838 , and  842  through  846  are deleted. Steps  814 ,  818 , and  820  are modified as follows: 
   In step  814 , the value of the variable CS_NS_count is ascertained. If the value of the variable CS_NS_count is equal to 1, the method continues in step  816 . If the value of the variable CS_NS_count is greater that 1, the method continues in step  818 . Otherwise, the method continues in step  840 . 
   In step  818 , the AT re-points the DRC to the candidate sector identified by the variable count that has the highest quality forward link. The method continues in step  820 . 
   In step  820 , the variable CS_NS is set to zero. The method returns to the credit accumulation phase. 
   Those of ordinary skill in the art will recognize that although the various embodiments were described in terms of flowcharts and methods, such was done for pedagogical purposes only. The methods can be performed by an apparatus, which in one embodiment comprises a processor interfaced with a transmitter and a receiver or other appropriate blocks at the AT and/or AP. 
   Those of skill in the art would understand that information and signals may be represented using any of a variety of different technologies and techniques. For example, data, instructions, commands, information, signals, bits, symbols, and chips that may be referenced throughout the above description may be represented by voltages, currents, electromagnetic waves, magnetic fields or particles, optical fields or particles, or any combination thereof. 
   Those of skill would further appreciate that the various illustrative logical blocks, modules, circuits, and algorithm steps described in connection with the embodiments disclosed herein may be implemented as electronic hardware, computer software, or combinations of both. To clearly illustrate this interchangeability of hardware and software, various illustrative components, blocks, modules, circuits, and steps have been described above generally in terms of their functionality. Whether such functionality is implemented as hardware or software depends upon the particular application and design constraints imposed on the overall system. Skilled artisans may implement the described functionality in varying ways for each particular application, but such implementation decisions should not be interpreted as causing a departure from the scope of the present invention. 
   The various illustrative logical blocks, modules, and circuits described in connection with the embodiments disclosed herein may be implemented or performed with a general purpose processor, a digital signal processor (DSP), an application specific integrated circuit (ASIC), a field programmable gate array (FPGA) or other programmable logic device, discrete gate or transistor logic, discrete hardware components, or any combination 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. A processor may also be implemented as a combination of computing devices, e.g., 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 such configuration. 
   The steps of a method or algorithm described in connection with the embodiments disclosed herein may be embodied directly in hardware, in a software module executed by a processor, or in a combination of the two. A software module may reside in RAM memory, flash memory, ROM memory, EPROM memory, EEPROM memory, registers, hard disk, a removable disk, a CD-ROM, or any other form of storage medium known in the art. An exemplary storage medium is coupled to the processor such the processor can read information from, and write information to, the storage medium. In the alternative, the storage medium may be integral to the processor. The processor and the storage medium may reside in an ASIC. The ASIC may reside in a user terminal. In the alternative, the processor and the storage medium may reside as discrete components in a user terminal. 
   The previous description of the disclosed embodiments is provided to enable any person skilled in the art to make or use the present invention. Various modifications to these embodiments will be readily apparent to those skilled in the art, and the generic principles defined herein may be applied to other embodiments without departing from the spirit or scope of the invention. Thus, the present invention is not intended to be limited to the embodiments shown herein but is to be accorded the widest scope consistent with the principles and novel features disclosed herein. 
   A portion of the disclosure of this patent document contains material, which is subject to copyright protection. The copyright owner has no objection to the facsimile reproduction by anyone of the patent document or the patent disclosure, as it appears in the Patent and Trademark Office patent file or records, but otherwise reserves all copyright rights whatsoever.