Patent Publication Number: US-6662019-B2

Title: Power control and transmission rate parameters of a secondary channel in a wireless communication system

Description:
BACKGROUND OF THE INVENTION 
     This invention relates to wireless communication systems and, more particularly, to the transmission of data in such systems. 
     In wireless communication systems generally, base stations transmit signals to mobile terminals over a communication link referred to as a forward link, and mobile terminals transmit signals to base station over a communication link referred to as a reverse link. When a call—a communication session between a base station and a particular mobile terminal—is set up, a primary channel is set up on both a forward and reverse link. The primary channel can be used to transmit voice, data, and/or so-called signaling information, and transmits the signal at a particular, typically a fairly low, transmission rate. If it is desired to transmit a signal at a higher transmission rate, for example for a data transmission having a large amount of data, the wireless communication system may be able to set up a secondary channel—a communication channel over which signals may be transmitted at the same or at a higher transmission rate than that of the primary channel. The secondary channel is typically set up only over the particular communication link, i.e. forward or reverse, over which it is desired to transmit the signal. 
     The way in which the secondary channel is set up takes into account the fact that data is often bursty, meaning that it is transmitted in bursts interspersed with periods of inactivity during which no data is transmitted. Typically, the secondary channel is maintained only for the duration of each data burst. Between data bursts, there is no secondary channel assigned to the call, whereas there is a primary channel maintained for the duration of the call. 
     The transmission rate of the burst on the secondary channel is a critical factor affecting the efficiency of the wireless communication system. An unnecessarily low transmission rate leads to an unnecessarily long time to transmit the data and an inefficient use of air bandwidth resources. On the other hand, a too high transmission rate can result in a such a large amount of system resources being allocated to the call as to compromise the system&#39;s ability to service other calls, and in so-called sectors where such a large amount of resources are allocated it can cause the equipment servicing the sector to enter into overload. 
     Usually, the main factor that limits how high a transmission rate can be used on the secondary channel is the power needed to transmit the signal, and in particular the initial power level on the secondary channel. Thus, the initial power level on the secondary channel is a critical factor affecting system efficiency. A too low initial power level results in an unacceptable level of received signal quality, which may cause so-called link errors. On the other hand, a too high initial power level leaves little transmit power for the system to service other calls, which degrades the overall data throughput and efficiency of the communication link. Another disadvantage of a too high initial power level is that the signal&#39;s interference with calls involving other mobile terminals is increased unnecessarily, requiring that the power level of the signals on these calls be increased. At best, this further reduces the power available to service other mobile terminals and reduces the access furnished to new calls. At worst, if there is not enough power available to increase the power level of the signals on the other calls, one or more of those other calls may have to be dropped. 
     Advantageously, the wireless communication system&#39;s power control will eventually adjust the power level to produce an efficient power level that will result in an acceptable level of received signal quality without causing unnecessarily strong interference with calls involving other mobile terminals. However, during the time it takes power control to accomplish this, if the initial power level was too high, the signal will cause unnecessarily strong interference with other calls and leave little transmit power for the system to service other calls. If the initial power level was too low, then, during the time it takes the power control to adjust it, the signal will be received with an unacceptable level of received signal quality. Additionally, if there is a large difference between the initial power level and the efficient power level, then the power control may not even be able to adjust the power level to the efficient power level before the burst is over. 
     Therefore, it is desirable for the wireless communication system to accurately estimate the power level it will allocate to the burst initially. Typically, the wireless communication system will base the initial power level on the power level of a signal on the primary channel just before the start of the burst, as described, for example, in U.S. patent application Ser. No. 09/676,179 entitled “Forward Transmission rate Determination of High Data Transmission Rate Channels in CDMA Air Interface,” assigned to the present assignee and hereby incorporated by reference. 
     Once the initial power level is accurately estimated, it can be used to determine an efficient transmission rate, which is typically the highest transmission rate supportable by the available system resources. 
     SUMMARY OF THE INVENTION 
     The present inventors have recognized that the above-mentioned technique for determining the initial power level, and therefore the efficient transmission rate, of a burst may not provide accurate results under certain circumstances, as will now be described. During at least a portion of a call, a mobile terminal may be involved in a so-called soft handoff, in which it is communicating with more than one base station. The communication links between the mobile terminal and a particular base station are each referred to as a “leg” of the handoff. When a secondary channel is established, it can be established on all the legs of the handoff. However, having the secondary channel on more than one leg of the handoff requires a significant amount of system resources and design complexity. Therefore, when conditions permit, it is known to establish the secondary channel on fewer than all the legs of the handoff. In such a case however, the communication-link characteristics of the primary channel of a particular leg are no longer similar to the communication-link characteristics of the secondary channel. This is caused by many factors including the fact that the communication-link characteristics on each of the legs of the handoff are both different and rapidly changing, and that there is no longer so-called space diversity on the secondary channel. We have thus recognized that the power level of a signal on the primary channel of a particular leg just before the start of the burst on the secondary channel is not necessarily an accurate indication of an appropriate initial power level for the burst on the secondary channel. 
     The present invention is a technique that allows for a more efficient initial power level, and therefore a more efficient transmission rate, for a secondary channel communication, for example a burst, when the secondary channel is on fewer legs of a handoff, such as a soft handoff, than the primary channel. In accordance with the invention, the initial power level of the burst transmitted over a current secondary channel on a communication link that includes a primary channel and a previous secondary channel is a function of a power level on the previous secondary channel, i.e. of a previous burst transmitted over the previous secondary channel. For example, the initial power level of the burst can be based on the power level prior to, or at, the termination of the previous burst, where the termination of the previous burst was within a predetermined time interval of the start of the burst. Preferably, the current secondary channel is on the identical legs of the handoff as the previous secondary channel. Optionally, the initial power level of a burst can also be a function of the characteristics of the communication link of the primary channel, the previous secondary channel, and the current secondary channel. 
     In accordance with a feature of the invention, the transmission rate may be adjusted based on the initial power level determined as described above to obtain a more efficient transmission rate. Particularly, the transmission rate may be adjusted based on whether the initial power level of the burst is acceptable in light of the power available at the power amplifier. In particular, the transmission rate can first be determined based on the system resources other than power. The initial power level is then determined using the above method with that transmission rate. If the initial power level is greater than the power available at the power amplifier, a lower transmission rate is selected and the initial power level is determined again using the above method but at the lower transmission rate. 
    
    
     BRIEF DESCRIPTION OF THE DRAWINGS 
     FIG. 1 a  illustrates a portion of a wireless communication system; 
     FIG. 1 b  illustrates the channels and communication links on the legs of the handoff when the secondary channel is on all of the legs of the handoff; 
     FIG. 1 c  illustrates the channels and communication links on the legs of the handoff when the secondary channel is on fewer than all of the legs of the handoff; 
     FIG. 2 illustrates the secondary channel power level; and 
     FIG. 3 is a flowchart showing an illustrative secondary-channel initial power level technique and embodying the principles of the present invention. 
    
    
     DETAILED DESCRIPTION 
     FIG. 1 illustrates a wireless communications system, such as Code Division Multiple Access (CDMA) system  100 . The geographic area serviced by CDMA system  100  is divided into a plurality of spatially distinct areas called “cells.” For ease of analysis, cells  102 ,  104 , and  106  are typically approximated and schematically rep resented by hexagons in a honeycomb pattern. However, each cell is actually of an irregular shape that depends on the topography of the terrain surrounding the cell. Each cell  102 ,  104 ,  106  can be divided into a plurality of sectors, such as three 120° sectors. Cell  102  is divided into sectors  102   a ,  102   b , and  102   c ; cell  104  is divided into sectors  104   a ,  104   b , and  104   c ; and cell  106  is divided into sectors  106   a , and  106   b  and  106   c . Cell  102 ,  104 ,  106  contain base stations  112 ,  114 ,  116 , respectively, each of which includes equipment to communicate with Mobile Switching Center (“MSC”)  120 . MSC  120  is connected to local and/or long-distance transmission network  122 , such as a public switched telephone network. Each base station  112 ,  114 ,  116  also includes transmitters and/or receivers, and antennas. Typically, each base station includes different transmitters, receivers, and antennas for each sector that the base station serves. The base stations use the transmitters, receivers, and antennas to communicate with mobile terminals, such as mobile terminals  124 ,  126 . The base stations transmit signals to the mobile terminals over a communication link referred to as a forward link, and the mobile terminals transmit signals to the base station over a communication link referred to as a reverse link. 
     When a call—a communication session between a base station, such as base station  112 , and a particular mobile terminal, such as mobile terminal  124 —is set up, a primary channel is set up on both a forward and reverse link. (In some systems, the primary channel is referred to as a fundamental channel.) The primary channel can be used to transmit voice, data, and/or so-called signaling information, and transmits the signal at a particular, typically a fairly low, transmission rate. If it is desired to transmit a signal at a higher transmission rate, for example for a data transmission having a large amount of data, the CDMA system checks, as described below, whether it is able to and it is advantageous to set up a secondary channel—a communication channel over which signals may be transmitted at the same or at a higher transmission rate higher than that of the primary channel. (In some systems the secondary channel is referred to as a supplemental channel or as a data channel.) The secondary channel is typically set up only over the particular communication link, i.e. forward or reverse, over which it is desired to transmit the signal. 
     The way in which the secondary channel is set up takes account of the fact that data is often bursty, meaning that it is transmitted in bursts interspersed by periods of inactivity during which no data is transmitted. Typically, the secondary channel is maintained only for the duration of each data burst. Between data bursts, there is no secondary channel assigned to the call, whereas there is a primary channel maintained for the duration of the call. Thus, the duration of the burst is shorter than the duration of the communication on the primary channel. 
     To determine whether CDMA system  100  is able to set up the secondary channel, the CDMA system first determines if the equipment allows for the higher transmission rate. If it does, then the CDMA system determines if it is advantageous to set up the secondary channel. It does this by determining if the amount of data to be transmitted is large enough that it would be transmitted faster over the secondary channel than over the primary channel taking into account the fact that no data is transmitted over the secondary channel during its set up time. 
     The CDMA system then determines what resources are available for the secondary channel. These resources are the various system resources, which include the number of so-called radios available for the communication link(s) that the secondary channel will use, the number of Walsh codes—orthogonal spreading sequences—available for each of these communication links, the power level available for each of these communication links, the hardware and software resources available for each of these communication links (for example the channel elements, CPU capacity, and radios), and the maximum transmission rate supportable at each of these communication links. The available resources are used to determine the transmission rate and initial power level of a burst transmitted over the secondary channel. 
     The transmission rate of the burst on the secondary channel is a critical factor affecting the efficiency of the wireless communication system. An unnecessarily low transmission rate leads to an unnecessarily long time to transmit the data and an inefficient use of air bandwidth resources. On the other hand, a too high transmission rate can result in a such a large amount of system resources being allocated to the call as to compromise the system&#39;s ability to service other calls, and in so-called sectors where such a large amount of resources are allocated it can cause the equipment servicing the sector to enter into overload. 
     Usually, the main factor that limits how high a transmission rate can be used on the secondary channel is the power needed to transmit the signal, and in particular the initial power level on the secondary channel. Thus, the initial power level on the secondary channel is a critical factor affecting system efficiency. A too low initial power level results in an unacceptable level of received signal quality, such as for example an unacceptable frame error transmission rate (FER) for the particular type of transmission. The FER is the number of so-called frames that contain non-correctable errors divided by the total number of frames observed. An unacceptable FER would require that either the errored frames, or an entire segment of the signal be re-transmitted. On the other hand, a too high initial power level leaves little transmit power for the system to service other calls. Another disadvantage of a too high initial power level is that the signal&#39;s interference with calls involving other mobile terminals is unnecessarily increased, requiring that the power level of the signals on these calls be increased. At best, this further reduces the power available to service other mobile terminals. At worst, if there is not enough power available to increase the power level of the signals on the other calls, one or more of those other calls may have to be dropped and new requests are rejected. 
     Advantageously, the wireless communication system&#39;s power control will eventually adjust the power level to produce an efficient power level that will result in an acceptable level of received signal quality without causing unnecessarily strong interference with calls involving other mobile terminal. However, during the time it takes power control to accomplish this, if the initial power level was too high, the signal will cause unnecessarily strong interference with other calls and leave little transmit power for the system to service other calls. If the initial power level was too low, then, during the time it takes the power control to adjust it, the signal will be received with an unacceptable level of received signal quality. Additionally, if there is a large difference between the initial power level and the efficient power level, then the power control may not have enough time to converge to the efficient power level during the entire duration of the burst. 
     Therefore, it is desirable for the CDMA system to accurately estimate the power level it will allocate to the burst initially. Typically, the wireless communication system will base the initial power level on the power level of a signal on the primary channel just before the start of the burst, as described, for example, in U.S. patent application Ser. No. 09/676,179 entitled “Forward Transmission Rate Determination of High Data Transmission rate Channels in CDMA Air Interface,” assigned to the present assignee. Once the initial power level is accurately estimated, it can be used to determine an efficient transmission rate, which is typically the highest transmission rate supportable by the available system resources. 
     The present inventors have recognized that the above-mentioned technique for determining the initial power level, and therefore an efficient transmission rate, of a burst may not provide accurate results under certain circumstances, as will now be described. During at least a portion of a call, a mobile terminal, for example mobile terminal  126 , may be involved in a so-called soft handoff, in which it is communicating with more than one base station, for example base stations  112 ,  114 , and  116 . The communication links between the mobile terminal and a particular base station are each referred to as a “leg” of the handoff. As can be seen in FIG. 1 a , there is a leg  132 ,  134 , and  136  between mobile terminal  126  and each of the base stations  112 ,  114 , and  116  participating in the handoff, respectively. When a secondary channel is established, it can be established on all the legs of the handoff, as shown in FIG. 1 b . Each of the legs  132 ,  134 , and  136  includes a forward  142 ,  144 ,  146  and reverse  152 ,  154 , and  156  link between mobile terminal  126  and each of the base stations  112 ,  114 , and  116 , respectively. As described above, there is a primary channel  162 ,  164 , and  166  on each of the forward links  142 ,  144 ,  146 , respectively, and a primary channel  172 ,  174 , and  176  on each of the reverse links  152 ,  154 ,  156 , respectively. There is also a secondary channel  182 ,  184 ,  186  on the communication link of each of the legs over which data is to be transmitted, in this case forward links  142 ,  144 ,  146 , respectively. 
     However, having the secondary channel on more than one leg of the soft handoff requires a significant amount of system resources and under certain circumstances reduces system performance. Therefore, when conditions permit, it is known to establish the secondary channel on fewer than all the legs of the soft handoff. FIG. 1 c  shows such a case. In this case, each of leg  132 ,  134 , and  136  still includes forward  142 ,  144 ,  146  and reverse  152 ,  154 , and  156  links, and there is still a primary channel  162 ,  164  and  166 , and  172 ,  174  and  176  on each of the forward and reverse links, respectively. However, in this case the secondary channel  182  is only on the forward link of one of the legs, in this case leg  132 . There is no secondary channel on legs  134  and  136 . (Although the secondary channel is shown as being on one leg of the handoff, other combinations of secondary channels are possible. The secondary channels can be on any subset of the legs over which the primary channel is established.) 
     In such a case, the communication-link characteristics of the primary channel of a particular leg are no longer similar to the communication-link characteristics of the secondary channel. This is caused by many factors. One of these factors is that the communication-link characteristics on each of the legs  132 ,  134 , and  136  of the handoff are both different and rapidly changing. Thus, when the characteristics of the communication link of one of the legs, for example leg  132 , change drastically, such for example when the fading on forward link  142  changes drastically, the combined signal received by mobile terminal  126  may still be received with an acceptable level of signal quality because this signal is also transmitted on the other primary channels,  164 , and  166 . However, if secondary channel  182 &#39;s initial power level was based on the power level of this primary channel just after the characteristics changed drastically, then this initial power level will most likely not produce an acceptable received signal quality. 
     Another of the factors why the communication-link characteristics of the primary channel of a particular leg are no longer similar to the communication-link characteristics of the secondary channel is that there is no so-called space diversity on the secondary channel. When a signal is transmitted on several channels—for example, on the three primary channels  162 ,  164 , and  166 —all the information received on all three channels can be used to recover the transmitted information, increasing the reliability of the link. Because secondary channel  182  is on only one communication link  142 , it thus becomes more critical that the communication-link characteristics on this link do not produce a received signal with an unacceptable FER, since an unacceptable FER would reduce the reliability of the link. 
     The inventors have thus recognized that during a soft handoff the power level of a signal on primary channel  162  of leg  132  just before the start of the burst on secondary channel  182  is not necessarily an accurate indication of an appropriate initial power level for the burst over secondary channel  182 . 
     The present invention is a technique that allows for a more efficient initial power level, and therefore a more efficient transmission rate, for a burst on a secondary channel when the secondary channel is on fewer legs of a handoff, such as a soft handoff, than the primary channel. In accordance with the invention, the initial power level of the burst transmitted over a current secondary channel on a particular leg, or legs, is a function of a power level of a previous burst transmitted over a previous secondary channel on the identical leg, or legs, as the current secondary channel. For example, as shown in FIG. 2, the initial power level of burst  220 , i.e. the power level at the start of burst  220  (at time t 2 ) is based on the power level at the end of burst  210  shortly prior to the termination of the previous burst (at t 1 ). 
     Optionally, the initial power level of a burst can also be a function of the characteristics of the communication link of the primary channel, the previous secondary channel, and the current secondary channel. The characteristics of the communication link of the primary channel include: the 1) power level, 2) transmission rate, and 3) space diversity on the primary channel (i.e. the of the signal on the primary channel) at, or prior to, the end of the previous burst; and the 4) power level, 5) transmission rate, and 6) space diversity of the primary channel at or just prior to the start of current burst. The characteristic of the communication link of the current secondary channel includes the desired transmission rate of the current secondary channel and the space diversity of the current secondary channel. The characteristics of the communication link of the previous secondary channel include the power level of the previous secondary channel, and the transmission rate of the previous secondary channel and the space diversity of the current secondary channel. 
     As can be seen in FIG. 2, the power level at the end of the previous burst is a good indication for the initial power level of the current burst where the termination of the previous burst was within a predetermined time interval, for example within 3 seconds, of the start of the burst in systems meant to be used in low speed environments, and within a shorter time period in systems meant to be used in higher speed environments. Because the conditions of the communication links change over time, once enough time passes the conditions of the communication link are different enough that the same power level will no longer produce the same FER. The predetermined time interval is selected as a result of a tradeoff between a) the desire to be more sure that the conditions of the communication link have not changed, to increase the likelihood that the same power level will produce the same FER, and b) the desire to increase the predetermined time interval, to increase the circumstances in which the learned measurements can be reused, i.e., the power level of the current burst is a function of the previous burst. 
     When the power level at the end of the previous burst is not a good indication of the initial power level of the current burst, the initial power level has to be estimated independently of the previous burst. This is the case when the current burst is the first burst of the communication, for example burst  210 , or the first burst on this particular leg or set of legs, or when the time between the current and previous bursts is longer than the predetermined time interval, for example burst  230  and  240 . (Note that when the leg over which the previous secondary channel was established is not the leg over which the current secondary channel will be established, the power level at the end of the previous burst is not a good indication of the initial power level of the current burst.) 
     In the cases described in the previous paragraph, the initial power level of the current burst is determined using the power level of the primary channel and the power available at the power amplifier. Preferably, the initial power level is determined conservatively, by only allowing the initial power level to be at most a predetermined fraction, for example between 50% and 75%, of the power amplifier&#39;s available power. By allowing the initial power level to be at most a predetermined fraction of the power amplifier&#39;s power, the method leaves reserve power for the power control to increase the power level if necessary. The predetermined fraction is selected as a tradeoff between 1) the desire to leave enough reserve for the power control to be able to increase the power level, and 2) the desire to allow the initial power level to be large enough to be able to transmit the burst at the largest transmission rate allowed by the other system resources. 
     In accordance with an illustrative embodiment of the invention the transmission rate may be adjusted based on whether the initial power level of the burst at the transmission rate is acceptable in light of the power available at the power amplifier. For example, the transmission rate can be determined based on the system resources other than power. The initial power level is then determined using the above method with this transmission rate. If the initial power level is greater than the power available at the power amplifier a lower transmission rate is selected and the initial power level is determined using this transmission rate. 
     FIG. 3 illustrates the flow of the process of operation of CDMA system  100  in accordance with an embodiment of the present invention. The individual boxes in the flowchart of FIG. 3 are described as process steps. However, those boxes can be equally understood as representing program instructions stored in a memory of CDMA system  100  and executed by a processor of CDMA system  100 , to effectuate the respective process steps. 
     The operation of CDMA system  100  in accordance with an embodiment of the present invention is now described with reference to FIGS. 2 and 3. During a call that is in soft handoff, it is determined if it is desired to transmit a signal at a higher transmission rate than the transmission rate of the primary channel, step  300 . Typically, the MSC notifies the primary base station—the base station that processes the signaling information during the handoff—when the MSC has a large amount of data to be transmitted to one of the mobile terminals communicating with the primary base station. For example, the MSC notifies the primary base station by requesting that a secondary channel be set up. If there is no request for a secondary channel the base stations continue to transmit over the primary channels, step,  305 , and the process returns to step  300 . 
     If there is a request for a secondary channel, it is determined whether there are hardware and software resources and it is advantageous to set up a secondary channel, step  310 . If the answer in steps  310  is NO, all of the base stations participating in the soft handoff transmit the data on the primary channels, step  315 , and the process returns to step  300 . If the answer in step  310  is YES, it is determined on which legs of the handoff the secondary channel is to be established, step  320 . This can be performed in any manner. If the secondary channel is to be established on fewer legs than the primary channel, the leg, or legs, on which the secondary channel is to be established is referred to as an anchor leg, or anchor legs. 
     Then, in step  325 , it is determined if there is a previous burst on the identical legs as the ones determined in step  320  that ended less than the predetermined time interval ago. If there is no such burst, the answer in step  325  is NO, the system determines a conservative initial power level of the current burst based on the power level of the primary channel and the power amplifier&#39;s available power. One illustrative way of performing this step is by first determining the desired transmission rate of the secondary channel based on the available system resources, except for available power, step  330 . Then, multiplying the number of times the desired transmission rate is larger than the rate of the primary channel by the power level of the signal on the primary channel and by the number of legs over which the primary channel is established (typically, the number of legs of the handoff to calculate an initial power level, step  335 . The CDMA system then checks if this initial power level is greater than a predetermined fraction of the power amplifier&#39;s available power A AP , for example, (0.75×A AP ) step  340 . If it is greater than (0.75*A AP ) then a lower transmission rate is selected, step  345 , and the process returns to step  335  to recalculate the initial power level using this lower transmission rate. 
     If the initial power level is less or equal to (0.75*A AP ), then the CDMA system establishes the secondary channel and transmits a burst with this initial power level over the secondary channel, step  350 . As the burst is transmitted, the power control adjusts the power level to achieve an efficient power level on the secondary channel. Before the burst is completed, preferably at the end of the burst, the transmission rates of the secondary and primary channels are recorded and the power level of the signal on the primary channel and the power level of the burst on secondary channel are measured and recorded so they may be used for future secondary channel requests, step  355 . A time stamp is added to these measurements in order to determine their age when they are used in determining the initial power level of a future secondary channel, and the process returns to step  300 . 
     If the answer in step  325  is YES, i.e. there was a previous burst on the identical legs as the ones determined in step  320  that ended less than the predetermined time interval ago, then the system determines the desired transmission rate of the secondary channel based on the available system resources, except for available power, step  357  and proceeds to step  360 . Advantageously, in step  360 , the communication-link characteristics at the end of the previous burst are used to determine the initial power level of the current burst. Illustratively, equation 1 provides the power level at time t 2 , i.e. the initial power level of the current burst, where the chip energy E Ca  is used as a way of expressing power levels.                    (       E   Ca   S       E   Ca   P       )     BS          (     t   2     )       =         (       E   Ca   S       E   Ca   P       )     BS          (     t   1     )     *     [           R   SCH          (     t   2     )       *   space                 diversity                   offset        (     t   2     )       *     
                   rate                   offset        (     t   2     )       *       (       E   Ca   F       E   Ca   P       )     BS          (     t   2     )             R   SCH          (     t   1     )       *   space                 diversity                   offset        (     t   1     )       *     
                   rate                   offset        (     t   1     )       *       (       E   Ca   F       E   Ca   P       )     BS          (     t   1     )         ]               (   1   )                         
     Where: 
     R SCH (t)=the secondary channel&#39;s transmission rate at time t; 
     E Ca   F (t)=the primary channel&#39;s chip energy at time t on the leg on which the secondary channel will be established; 
     E Ca   S (t)=the secondary channel&#39;s chip energy at time t on the leg on which the secondary channel will be established; 
     E Ca   P (t)=the pilot signal&#39;s chip energy on the leg on which the secondary channel will be established at time t, where the pilot signal is a direct-sequence spread spectrum signal transmitted continuously by each base station; and 
     the subscript BS means that this is the energy at the base station. 
     The space diversity offset takes into account the space diversity of the secondary channel relative to the primary channel, which is based on the number of legs on which the primary channel is established, the number of legs on which the secondary channel is established, and on relative strength of the pilot signals on this communication link. The space diversity offset can be determined once, for example by computer simulation, and then tabulated and used in equation 1. The space diversity offset can be obtained by simulating a soft handoff and varying 1) the strength of the pilots, 2) the number of legs on which the primary channel is established, and 3) which of these legs the secondary channel will be established, i.e. on how many and on which ones. The space diversity offset will vary the most in the cases where the primary channel is established on either two or three legs, as the number of legs increases the value of the space diversity offset will start to converge. 
     The rate offset takes into account the gain due to the fact the value for the target FER—the FER produced by the efficient power level, changes based on transmission rates. Like, the space diversity offset, the rate offset can be determined once, for example by simulation, and then tabulated and used in equation 1. The rate offset can be obtained by simulating a soft handoff and varying the target FER. 
     Equation 1 is explained in more detail in the section below entitled Equation 1. 
     The ratio of the chip energy of the secondary channel to that of the pilot signal            (       E   Ca   S       E   Ca   P       )     BS          (     t   2     )                     
     obtained in equation 1 is the ratio of the initial power level of the secondary channel to power level of the pilot signal. The CDMA system then checks if this initial power level is greater than the power amplifier&#39;s available power A AP , step  365 . If it is greater than A AP  then a lower transmission rate is selected, step  370 , and the process returns to step  360  to recalculate the initial power level using this lower transmission rate. 
     If the initial power level is less or equal to A AP , then the CDMA system establishes the secondary channel and transmits a burst with this initial power level over the secondary channel, step  375 . As the burst is transmitted the secondary channel power control adjusts the power level to achieve an efficient power level on the secondary channel. Before the burst is completed, preferably at the end of the burst the transmission rates of the secondary and primary channels is recorded the power level of the signal on the primary channel and the power level of the burst on secondary channel are measured and recorded so they may be used for future secondary channel requests, step  380 . A time stamp is added to these measurements in order to determine their age when they are used in determining the initial power level of a future secondary channel, and the process returns to step  300 . 
     Equation 1 
     As can be seen in FIG. 2, when one burst, for example burst  220  starts shortly after the end of another burst, such as burst  210 , the power level at the end of burst  210  is a good indication for the initial power level of burst  220 . If there were any changes in communication-link characteristics between the time when the previous burst ended, t 1 , and the time when the next burst started, t 2 , they would be on both the primary and on the secondary channels, so the ratio of the bit energy between the secondary channel and primary channel at time t 1  and t 2  should be equal. Thus,                    E   b   S          (     t   1     )           E   b   F          (     t   1     )         =         E   b   S          (     t   2     )           E   b   F          (     t   2     )                 (   2   )                         
     Since the space diversity and secondary channel transmission rate may have also changed between t 1  and t 2  equation 2 should be corrected for this, resulting in:                    E   b   S          (     t   1     )         space                 diversity                                  offset        (     t   1     )       *   rate                   offset        (     t   1     )       *       E   b   F          (     t   1     )           =         E   b   S          (     t   2     )           space                 diversity                   offset        (     t   2     )         +     rate                   offset        (     t   2     )       *       E   b   F          (     t   2     )                     (   3   )                         
     In a CDMA system:                      E   b   S          (   t   )       =       W       R   SCH          (   t   )                E   Ca   S          (   t   )           ,          
             (   4   )                     E   b   F          (   t   )       =       W       R   FCH          (   t   )                E   Ca   F          (   t   )           ,           (   5   )                         
     where: 
     R FCH (t)=primary channel&#39;s transmission rate at time t; 
     W=CDMA chip rate (1.2288 M Chips/sec); 
     E b   F (t)=primary channel&#39;s bit energy at the base station at time t; 
     E b   S (t)=secondary channel&#39;s bit energy at the base station at time t. 
     The rate on the primary channel does not change 
     
       
           R   FCH ( t   1 )= R   FCH ( t   2 )  (6) 
       
     
     Substituting equations (4), (5), and (6) into equation (3) produces equation 1:                    (       E   Ca   S       E   Ca   P       )     BS          (     t   2     )       =         (       E   Ca   S       E   Ca   P       )     BS          (     t   1     )     *     [           R   SCH          (     t   2     )       *   space                 diversity                   offset        (     t   2     )       *     
                   rate                   offset        (     t   2     )       *       (       E   Ca   F       E   Ca   P       )     BS          (     t   2     )             R   SCH          (     t   1     )       *   space                 diversity                   offset        (     t   1     )       *     
                   rate                   offset        (     t   1     )       *       (       E   Ca   F       E   Ca   P       )     BS          (     t   1     )         ]               (   1   )                         
     The foregoing is merely illustrative and various alternatives will now be discussed. The illustrative embodiment is described with the base stations participating in a soft handoff. However, in alternative embodiments of the invention the base stations can be in softer handoff. A call is in softer handoff when the mobile terminal receives fairly strong pilot signals from two of more sets of communication equipment, typically located in the same base station, each set of communication equipment serving a different so-called sector of a cell of the wireless communication system. There is a leg of the handoff between each set of equipment and the mobile terminal. 
     The illustrative embodiment is described with the wireless communication system being a CDMA system. However, in alternative embodiments the wireless communication system can be any system capable of establishing secondary channels. This method is particularly useful in wireless communication systems where the secondary channel can be established on fewer than all of the legs of a handoff. This method is also particularly useful in wireless communication systems where the conditions of the communication links change, such for example when the fading on the communication links changes, and particularly when the fading changes drastically. 
     The illustrative embodiment is described with three base stations participating in a soft handoff. However, in alternative embodiments any number of base stations can participate in the soft or softer handoff. 
     In the illustrative embodiment, the process steps of FIG. 3 are performed in the base station that is one end of the leg over which the secondary channel is established. However, in alternative embodiment of the invention these steps can be performed in any part of the wireless communication system, for example in the MSC. 
     In the illustrative embodiment the process steps of FIG. 3 are implemented using software. One skilled in the art will realize that in alternative embodiments hardware can be used to implement the functionality of this software. 
     The illustrative embodiment is described with base station including a transmitter and a burst being transmitted over the forward link, i.e. from the base station to the mobile terminal. However, one skilled in the art will realize that the burst can be transmitted over the reverse link, i.e. from the mobile terminal to base station, in addition to, or instead of, from the base station to the mobile terminal using the methods described above. Typically, in most current system, on the reverse link, the secondary channel is set up on the same legs as the primary channel. In such a case, is advantageous to use the power of the primary channel to estimate the initial power level of a burst on the secondary channel. However, if on the reverse link the secondary channel is set up on a subset of the legs of the primary channel, then it is advantageous to use the method of the present invention to determine the initial power level and the transmission rate for the burst on the secondary channel over the reverse link. 
     In the illustrative embodiment of the invention the transmission rate is adjusted based on the initial power level. In alternative embodiments of the invention, the initial power level can be used in determining other characteristics of the communication link in addition to, or instead of, the transmission rate. 
     In the illustrative embodiment of the invention the power that can be used for the initial power level is all or a predetermined fraction of the amplifier&#39;s available power. In alternative embodiments of the invention, some power may be reserved for other uses. Thus, the power that can be used for the initial power level can be just the power that is available of the secondary channel. 
     The present invention is applicable in system where the secondary channels can support only transmission rates that are a whole number multiple of the transmission rate of the primary channel, as well as systems that do not place this restriction on the secondary channel. 
     Thus, while the invention has been described with reference to a preferred embodiment, it will be understood by those skilled in the art having reference to the specification and drawings that various modifications and alternatives are possible therein without departing from the spirit and scope of the invention.