Abstract:
A method and system for avoiding data loss in communications systems. The method and system achieve their objects via communications equipment adapted to do the following: designate a first data-producing system controlled by a first clock; designate a second data-producing system controlled by a second clock; record a timing mismatch between the first clock and the second clock; and dynamically adjust data flow between the first and the second system in response to the recorded timing mismatch.

Description:
BACKGROUND OF THE INVENTION 
     1. Technical Field 
     The present invention relates, in general, to a method and system, to be utilized with wireless communications systems, having cellular architectures which utilize digital clocked systems (such as Time Division Multiple Access (TDMA), Code Division Multiple Access (CDMA), or similar technologies), and which interface with public switched telephone networks (PSTNs). In particular, the present invention relates to a method and system, to be utilized with wireless communications systems, having cellular architectures which utilize digital clocked systems (such as TDMA, CDMA, or similar technologies), and which interface with PSTNs, wherein the method and system increase the reliability of such wireless communications systems by avoiding communication failures at the wireless communication system-PSTN system interfaces. 
     2. Description of the Related Art 
     The present invention is related to wireless communication systems, and, in particular, to wireless communications systems which have both a cellular architecture (e.g., cellular telephony, personal communications systems) and which utilize CDMA (or similar technologies) and which interface with public switched telephone networks (PSTNs). Wireless communication refers to the fact that transmission between sending and receiving stations occurs via electromagnetic radiation (e.g., microwave) not guided by any hard physical path. Cellular architecture refers to the fact that the wireless system effects service over an area by utilizing a system that can (ideally) be pictographically represented as a cellular grid. CDMA stands for Code Division Multiple Access, which is a type of spread spectrum technology, originally developed for military application and thereafter adapted for civilian use. 
     Wireless cellular communication utilizing CDMA is the latest incarnation of a technology that was originally known as mobile telephone systems. Early mobile telephone system architecture was structured similar to television broadcasting. That is, one very powerful transmitter located at the highest spot in an area would broadcast in a very large radius. If a user were in the usable radius, then that user could broadcast to the base station and communicate by radio telephone to the base station. However, such systems proved to be very expensive for the users and not very profitable to the communication companies supplying such services. The primary limiting factor, or problem, of the original mobile telephone systems was that the number of channels available for use was limited due to severe channel-to-channel interference within the area served by the powerful transmitter. 
     This problem was solved by the invention of the wireless cellular architecture concept. The wireless cellular architecture concept utilizes geographical subunits called “cells” and encompasses what are known as the “frequency reuse” and “handoff” concepts. A cell is the basic geographic unit of a cellular system. Cells are defined by base stations (a base station consists of hardware located at the defining location of a cell and includes power sources, interface equipment, radio frequency transmitters and receivers, and antenna systems) transmitting over small geographic areas that are represented (ideally) as hexagons. The term “cellular” comes from the honeycomb shape of the areas into which a coverage region, served via two or more base stations, is divided when the mathematically ideal hexagonal shape is used to represent the usable geographic area of each of the two or more base stations. It is to be understood that, although the mathematically ideal shape of the cell is a hexagon, in practicality each cell size varies dependent upon the landscape (e.g., a base station transmitting on a flat plane will closely approximate the ideal hexagon, whereas a base station transmitting in a valley surrounded by hills will not closely approximate a hexagon due to the interference from the surrounding hills). 
     The first large-scale wireless communications system utilizing cellular architecture in North America was the Advanced Mobile Phone Service (AMPS) which was released in 1983. With the introduction of AMPS, user demand for bandwidth was initially low until users became acquainted with the power of the system. However, once users became acquainted with the power of cellular, the demand for the service increased. Very quickly, even the extended number of channels available utilizing the cellular concepts of reduced power output and frequency reuse were quickly consumed by user demand in certain geographic areas, and a problem arose with respect to capacity. 
     Engineers responded to the problem by devising the Narrowband Analog Mobile Phone Service (NAMPS). NAMPS utilizes frequency division multiplexing to transmit three transmit/receive channels in the same bandwidth wherein AMPS had previously only transmitted one transmit/receive channel. Thus, NAMPS essentially tripled the capacity of AMPS. However, even though NAMPS essentially tripled the capacity of AMPS, the extended number of channels available with NAMPS were quickly consumed by user demand in certain geographic areas, and a problem again arose with respect to capacity. 
     Engineers responded to this new problem by devising Digital AMPS (or DAMPS, also known as TDMA). In DAMPS/TDMA time division multiple access techniques are utilized to multiplex user data together. Furthermore, digital data compression techniques are utilized at both the transmission and reception ends. These techniques give rise to increased capacity, and clarity, even exceeding that of NAMPS. However, as was the case with both AMPS and NAMPS, the increased bandwidth capacity of DAMPS/TDMA has been quickly consumed by user demand in certain geographic areas. 
     Subsequent attempts to increase cellular telephony bandwidth capacity tended to be variations on the foregoing described themes. However, it became apparent that some new communications technology would be necessary to give rise to any significant increase in bandwidth beyond that available with the foregoing described technologies. It was decided within the industry that such new technology would be standard CDMA, which stands for Code Division Multiple Access. 
     Notice that in all the foregoing described technologies, the method of using multiple transmit/receive channels with each such transmit/receive channel utilizing a different pair of frequencies was maintained throughout. Standard CDMA breaks completely with this method of communication. 
     Standard CDMA utilizes cellular architecture and a type of hand-off. However, in standard CDMA, transmission and reception is done by all users on the same frequency. Standard CDMA is able to achieve this feat by insuring that the signals from different users are adjusted such that the signals do not interfere with each other to the point of being unable to understand the messages from the different users. 
     The way in which standard CDMA works is somewhat analogous to a situation in which two English speaking persons are communicating in a room wherein many other non-English speakers are also communicating in a language which the two English speakers do not understand. Since the two English speakers do not understand the language spoken by the non-English speakers in the room, the conversations of their non-English-speaking counterparts will be interpreted by the two English speakers as meaningless “noise.” Consequently, since the English speakers will attach no meaning to the “noise,” the English speakers will be able to disregard the “noise” and continue to engage in their conversation provided that they both speak loudly enough so that each can be understood by the other despite the “noise” generated by their non-English-speaking counterparts. This is true even though all persons in the room are talking, or communicating, in the same band of sound frequencies which the human ear can hear. 
     Standard CDMA is able to achieve the same affect by modulating the signal of each user within a particular cell with a “pseudo-noise” code which, in effect, will make each user in the cell appear as if each user were, in effect, “speaking a different language,” thereby insuring that the meaning of a signal generated by one user within the cell will not be drowned out by the meaning contained within the signal generated by one or more other users in the cell. Provided, of course, that each user speaks “loudly” enough (or transmits enough power) to be understood over the “noise” generated by the other users in the CDMA cell. 
     Standard CDMA utilizes digital data technology to achieve the foregoing. Standard CDMA utilizes complex digital codes to modulate user data prior to transmission within a cell. The standard CDMA pseudo-noise codes are chosen such that a modulated signal, when transmitted upon a carrier frequency within the cell, approximates white (or Gaussian) noise, and does not greatly interfere with any other signal transmitted upon the same carrier frequency within the cell. Upon reception, a similar pseudo-noise code is used to demodulate the signal and recover the data that was transmitted. 
     When digital data technology is utilized with the standard CDMA pseudo-noise codes, it is necessary for all transmitters and receivers within a cell to be synchronized to the same digital clock. This synchronization is provided by use of a “pilot” signal which is transmitted by the base station. Each mobile subscriber unit within a cell “locks” to this pilot signal and thereafter utilizes it as the clock signal for digital data-processing. 
     In standard CDMA, each base station transmits and receives on the same carrier frequency. Furthermore, in standard CDMA, each base station transmits the same period digital code which is utilized as the pilot signal within each cell. Ordinarily, such a situation would give rise to severe interference between cells. Standard CDMA avoids this problem by phase-shifting (or time-staggering) the pilot signal, or digital code, transmitted within adjacent cells. Within standard CDMA, the carrier signal, pilot code, pseudo-noise codes, and phase-shifting (or time-staggering) of the pilot codes utilized in adjacent cells have all been chosen to work together such that inter-cell interference is minimized. Thus, not only does standard CDMA ensure that users in each cell appear to each other as if they are “speaking different languages,” but standard CDMA ensures that adjacent cells appear to each other “as if” each cell was in fact “speaking a different language.” 
     It has been stated that when digital data technology is utilized with the standard CDMA pseudo-noise codes, it is necessary for all transmitters and receivers within a cell to be synchronized to the same digital clock. This synchronization is provided by use of a “pilot” signal which is transmitted by the base station. Each mobile subscriber unit within a cell “locks” to this pilot signal and thereafter utilizes it as the clock signal for digital data-processing. The question naturally arises as to the origin of the clock signal used by the CDMA system. 
     The answer is that the clock signal originates with the Global Positioning System (GPS). The GPS is a network of geostationary satellites which is utilized to provide precise global positioning. Each GPS satellite contains a clock synchronized to the clocks on the other GPS satellites. One of the features of the GPS is that it emits a “ping,” or clock signal, every 20 msec. Because each GPS satellite is geostationary, each GPS satellite is at roughly the same distance from the earth&#39;s surface (i.e. Geostationary Height). Consequently, each “ping” from a GPS satellite reaches the earth&#39;s surface essentially simultaneously. 
     Because each “ping” reaches the earth&#39;s surface essentially simultaneously, CDMA utilizes such pings as its system clock. Thus, the GPS 20 msec ping provides an effective “clock” to synchronize the CDMA transmitters and receivers, and is consequently utilized for that purpose. Thus, the GPS provides an effective way to synchronize a CDMA network which may be spread over a large geographic area. 
     In many rapidly developing, but previously undeveloped, areas of the world, such as the former Soviet Union, and the Central and South American republics, only CDMA systems are in place. That is, no substantial pre-existing PSTNs are in place. However, in long-developed areas of the world, such as the United States of America, Canada, and the European Union, there are extensive infrastructures of PSTNs present. In such areas, it is necessary for CDMA systems to interface with the PSTN systems in order for CDMA to be commercially viable and to provide seamless communications services to the residents of such areas. Such interfacing poses multiple problems, but one of the most significant arises from the fact that the timing signals utilized by the CDMA systems and the PSTN systems are not synchronized. 
     A PSTN is a common carrier network that provides circuit switching for the general public. It is usually a domestic communications network that is accessed by telephones, private branch exchange trunks, and data equipment such as modems. One common type of data carried by PSTNs is digitized voice data. 
     The human voice amounts to an analog (continuous time) signal. However, from a data communications standpoint, it has been found that transmission of the human voice in digital (discrete time) format produces more acceptable results. Consequently, it is necessary to convert the human voice, which is an analog signal, to a digital signal. After transmission, the digital signal is a re-converted to an analog signal which the human ear can hear. 
     It has been found empirically, that a human voice signal containing at least frequencies up to the 4000 hertz range is acceptable to most listeners. Consequently, it is necessary to sample the voice signal at two times that frequency such that frequencies up to the 4000 hertz range can be adequately captured. That is, it has been found that sampling a voice signal 8,000 times a second will result in acceptable performance. 
     One way in which the analog to digital conversion is done is known as Pulse Code Modulation (PCM). In PCM systems the analog signal is sampled once every 8000 seconds, which equates to 1 PCM sample every 125 micro-seconds. When a sample occurs, the magnitude of the analog voice signal is noted. Thereafter, some relative scale is utilized to denote that magnitude. Normally, three bits (binary information units, typically denoted by the symbols “0” and “1”) are utilized to quantize the analog signal digitally. 
     Since a PCM system samples data at specific time intervals, a clock signal is needed to synchronize the system. In a PSTN, such a clock signal is derived from what is known as the “PSTN Clock.” The PSTN Clock is derived from a centrally located atomic clock located at some central geographic location. There are various of these PSTN Clocks scattered throughout the world. However, for the purposes of this discussion, the central fact to be gleaned is that such PSTN Clocks are not synchronized with the GPS clocks utilized to synchronize the CDMA systems. This lack of synchronization can give rise to several problems, one of which is illustrated in FIG.  1 . 
     Refer now to FIG.  1 . FIG. 1 is a partially schematic diagram which will be used to illustrate problems that arise due to the fact that the clocks used to control CDMA systems and PSTN systems are not synchronized. Shown in FIG. 1 is CDMA voice coding subsystem  100 . On the right-hand side of FIG. 1 appears PSTN system  102 . PSTN system  102  is utilizing PCM and is delivering a PCM input stream  104  to CDMA voice coding subsystem  100 . Further shown is that PSTN system  102  utilizes PSTN clock  106 , which as has been discussed, is some type of atomic clock at some defined ground-based location. 
     Shown is that within CDMA voice coding system  100  resides a digital signal processor (DSP)  110 . Contained within DSP  110  is PCM-CDMA encoder  112  which accepts PCM sample blocks, signal processes (or encodes) them, and delivers such encoded blocks to CDMA system  108  which appears on the left-hand side of FIG.  1 . 
     Upon receipt of each PCM sample, PCM sample detection circuitry (not shown) interrupts DSP  100  in order to inform DSP  100  that a PCM sample has been received on the PSTN input stream  104 . In response to this interrupt, DSP  100  keeps a count of the number of PCM samples received during a particular time interval; furthermore, DSP  100  loads the received PCM sample into a PCM sample input buffer (not shown). 
     Shown is that CDMA system  108  is controlled, or synchronized by, GPS clock  114 . Consequently, when the 20 msec GPS “ping” occurs, CDMA system  108  alerts DSP  110  to the fact that the 20 msec ping has occurred. In response, PCM-CDMA encoder  112  retrieves the stored PCM samples from the PCM sample input buffer (not shown), effectively emptying the PCM sample input buffer (not shown) wherein the previously received PCM samples had been stored. After retrieval, PCM-CDMA encoder  112  processes the retrieved PCM sample block and creates a CDMA packet and places the created CDMA packet into a CDMA packet output buffer (not shown). Thereafter, the created CDMA packet is transmitted from CDMA voice coding subsystem  100  under the dictates of GPS clock  114 . The CDMA packet leaves CDMA voice coding subsystem  100  via CDMA packet output stream  116 . 
     An essentially reciprocal operation occurs in the reverse direction. That is, CDMA packets enter CDMA voice coding subsystem  100  via CDMA packet input stream  118 . Upon receipt of each CDMA packet, CDMA packet detection circuitry (not shown) interrupts DSP  100  in order to inform DSP  100  that a CDMA packet has been received on the CDMA packet input stream  118 . In response to this interrupt, DSP  100  places the received CDMA packet into a CDMA packet input buffer (not shown) and directs CDMA packet-PCM sample decoder  120 , upon completion of any processing it may be engaged in, to thereafter accept the received CDMA packet, decode it into PCM samples, and place the PCM samples into a PCM sample output buffer (not shown). Thereafter, the PCM samples are read out of the PCM sample output buffer under the dictates of the PSTN clock  106 . 
     Notice that, irrespective of the direction of flow through CDMA voice coding system  100 , since PSTN clock  106  and GPS clock  114  are not exactly synchronized (because the clocks do not communicate), some potential data loss is likely. It has been noted that GPS clock  114  produces a ping every 20 msec. It is also been noted that the PCM system utilizes PSTN clock  106  pulses to produce a PCM sample every 125 micro-seconds (e.g., 1 sec/8,000 samples). Consequently, if PSTN clock  106  and GPS clock  114  were perfectly synchronized (i.e., 20 msec measured on GPS clock  114  was exactly the same as 20 msec measured on PSTN clock  106 , and the transition edges of the clocks occurred precisely the same instances), there would be 160 PCM samples clocked through CDMA voice coding subsystem  100 , on both PCM input stream  104  and PCM output stream  122 , respectively, every 20 milliseconds. 
     Unfortunately, for the reasons discussed above, PSTN clock  106  and GPS clock  114  are not synchronized. That is, during the normal course of operation of the systems the transition edges of the clock do not occur at the same time or at the same rate (i.e., 20 msec as measured by GPS clock  114  will tend to be slightly different that 20 msec as measured by PSTN clock  106 ). Furthermore, in the event that the clocks differ by more than 1 PCM sample interval (i.e., by more than 125 micro-seconds) sample transmission will eventually begin to trail behind that necessary and eventually data will be dropped due to the finite size of the buffers. This reality can be made clear by a simple example related to PCM input stream  104 . 
     Assume that the 20 msec ping of GPS clock  114  is either “lagging” or “leading” PSTN clock  106  by a 250 micro-seconds. That is, for every 20 msec deemed to have elapsed by GPS clock  114 , according to PSTN clock  106  the elapsed time appears to be 20 msec plus/minus 250 micro-seconds. Admittedly, from the standpoint of a 20 msec interval, plus/minus 250 micro-seconds does not seem that significant, since such lagging or leading amounts to only 1.25% of the 20 msec period. 
     However, when viewed from the standpoint of the buffers (not shown) of CDMA voice coding subsystem  100 , it can be seen that the such leading or lagging can become very significant. If GPS clock  114  is lagging PSTN clock  106  by 250 micro-seconds, then when GPS clock  114  pings, 162 PCM samples will have been collected from PCM input stream  104 , rather than PCM samples. Consequently, when PCM-CDMA packet encoder  112  removes 160 PCM samples from the PCM sample input buffer (not shown), two residual PCM samples will remain in the PCM sample input buffer (not shown). 
     Assuming that GPS clock  114  and PSTN clock  116  remain unsynchronized it can be seen that the PCM packet input buffer (not shown), which has finite capacity, will eventually become full and consequently data will be lost. 
     If GPS clock  114  is leading PSTN clock  106  by 250 micro-seconds, then when GPS clock  114  pings, 158 PCM samples will have been collected from PCM input stream  104 , rather than 106 PCM samples. Consequently, when PCM-CDMA packet encoder  112  removes the PCM samples from the PCM sample input buffer (not shown), it will find that only 158 PCM samples are present and consequently will be unable to construct the appropriately sized CDMA packet. 
     An analogous state of affairs exists with respect to CDMA packet input buffers (not shown) and the PCM output, or transmit, buffers (not shown). That is, if GPS clock  114  is lagging PSTN clock  106  by 250 micro-seconds, then the when the GPS clock  114  pings, two PCM sample intervals will have transpired with no PCM samples being ejected on the PCM output stream  122 . If this state of affairs continues, there will be noticeable “data drop” at relatively periodic intervals, which has been empirically determined to provide unacceptable service to users. That is, a human user can hear and be conscious of such “data drops” and finds such occurrences rankling. Conversely, if GPS clock  114  is leading PSTN clock  106  by 250 micro-seconds, when GPS clock  114  pings, there will still be to PCM samples in the PCM sample output buffer (not shown). Consequently, if this state of affairs continues, the PCM sample output buffer (not shown) will eventually fill and data will be lost. 
     The foregoing problems associated with the potential CDMA clock and PSTN clock mismatching have been recognized in the prior art. With respect to the PCM sample input buffer problem noted above, the solution that has been effected under the prior art has been to constantly interrupt DSP  110  upon every receipt of a PCM input sample on PCM input stream  104 . These interrupts allow DSP  110  to keep a running count of the number of PCM samples in the PCM sample input buffer. Consequently, when GPS clock  114  pings, DSP  110  can determine if more or less PCM samples are present in the PCM sample input buffer then there should be. In response to such determination, DSP  110  either discards the excessive samples present (e.g., when the samples in the PCM sample input buffer are greater than 160 in number), or duplicates the last PCM sample in the PCM sample input buffer when an inadequate number of PCM samples is present (e.g., when the samples in the PCM sample input buffer are less than 160 in number). 
     An analogous solution has been applied to the problems associated with the CDMA packet input buffers and PCM sample output buffers discussed above. That is, DSP  110  is interrupted every time a PCM sample is clocked out of the PCM sample output buffer. Consequently, DSP  110  is able to keep count of the number of PCM samples in the PCM sample output buffer and is able to discard PCM samples or add PCM samples to the PCM sample output buffer as appropriate in order to ensure that no CDMA input packets are dropped such that no data outage is experienced by users of PSTN system  102 . That is, DSP  110 , by using a count kept based on the multiple interrupts, is able to control the PCM sample output buffer such that data drop is not detectable by a human user and such that the CDMA packet input buffer does not overflow. 
     While the foregoing described solutions to the problems associated with lack of synchronization between CDMA system clocks and PSTN system clocks works well, it is also apparent that the system generates a tremendous number of interrupts to DSP  110  in order to effectuate the solution. That is, under the present scheme, DSP  110  is interrupted 160 times in every 20 msec interval (as measured by the PSTN clock) with respect to PCM input stream  104 . In addition, DSP  110  is interrupted approximately 160 times in every 20 msec interval (as measured by the PSTN clock) with respect to PCM samples output on PCM output stream  122  (the interrupts are approximately 160 because, as has been discussed, the number of PCM samples actually placed in PCM sample output buffer depend upon the mismatch between the CDMA and PSTN clocks). Consequently, the present solutions to the foregoing identified problems results in approximately 320 interruptions of DSP  110  every 20 msec or 16,000 interruptions per second. From a computational standpoint, such a high number of interruptions is inefficient. That is, since DSP  110  is responsible for controlling all processing within CDMA voice coding subsystem  100 , it is apparent that it would be advantageous to reduce the number of interrupts of DSP  110  necessary to achieve the solution to the foregoing problems. 
     In addition to the foregoing noted problems, there were additional motivations for the present invention. One such motivation is that while in traditional methods there is only one call being handled per DSP  110 , there is an impetus in the marketplace to go to multi-call: more than one call being handled per DSP  110 . As can be seen, if an attempt to go to multi-call is made, the foregoing noted problems multiply (e.g., there are now as many interruptions of DSP  110  per call as before, except that these interruptions will be multiplied by the number of calls being handled by DSP  110 ). Thus, marketplace pressure also indicates that it would be advantageous to find a way to maintain the efficacy of the prior art solution, yet do so in a way that reduces the number of interrupts per call. 
     It is therefore apparent that a need exists for a method and system which will provide a solution to the communication failure problems associated with lack of synchronization between CDMA system clocks and PSTN system clocks, but which will do so in a more computationally efficient way. 
     SUMMARY OF THE INVENTION 
     It is therefore one object of the present invention to provide a method and system to be utilized with wireless communications systems having cellular architectures which utilize digital clocked technologies (such as Time Division Multiple Access (TDMA), Code Division Multiple Access (CDMA) or similar spread spectrum technologies), and which interface with public switched telephone networks (PSTNs). 
     It is yet another object of the present invention to provide a method and system, to be utilized with wireless communications systems having cellular architectures which utilize digital clocked technologies (such as TDMA, CDMA or similar spread spectrum technologies), and which interface with PSTNs, wherein the method and system increase the reliability of such wireless communications systems by avoiding communication failures at the wireless communication system-PSTN system interfaces. 
     The method and system achieve their objects via communications equipment adapted to do the following: designate a first data-producing system controlled by a first clock; designate a second data-producing system controlled by a second clock; record a timing mismatch between the first clock and the second clock; and dynamically adjusting data flow between the first and the second system in response to the recorded timing mismatch. In one embodiment the first system is a CDMA system controlled by a GPS clock, and the second system is a PSTN system controlled by a PSTN clock. 
     The above, as well as additional objects, features, and advantages of the present invention will become apparent in the following detailed written description. 
    
    
     BRIEF DESCRIPTION OF THE DRAWINGS 
     The novel features believed characteristic of the invention are set forth in the appended claims. The invention itself, however, as well as a preferred mode of use, further objects, and advantages thereof, will best be understood by reference to the following detailed description of an illustrative embodiment when read in conjunction with the accompanying drawings, wherein: 
     FIG. 1 is a partially schematic diagram which will be used to illustrate problems that arise due to the fact that the clocks used to control CDMA systems and PSTN systems are not synchronized; 
     FIG. 2 depicts a system wherein one or more embodiments of the present invention may be practiced; 
     FIG. 3 constitutes a high-level logic flowchart which depicts an embodiment of the present invention; 
     FIG. 4 depicts a system wherein one or more embodiments of the present invention may be practiced; and 
     FIG. 5 constitutes a high-level logic flowchart which depicts an embodiment of the present invention. 
    
    
     DETAILED DESCRIPTION OF THE INVENTION 
     It was discussed in the background section that the lack of synchronization between CDMA system and PSTN system clocks gives rise to multiple problems. It was also discussed that prior art solutions to the problems result in a relatively large number of interrupts to the primary digital signal processor. 
     Embodiments of the present invention provide a solution to the foregoing identified problems arising from lack of synchronization between CDMA system clocks and PSTN system clocks, but without generating the relatively large number of interrupts to the primary digital signal processor. At least one of the embodiments of the present invention achieves the foregoing by removing the responsibility for buffer management from a digital signal processor and instead having the buffer management done via the use of a semi-autonomous processor which utilizes a new way of managing buffers and which communicates with the primary digital signal processor. 
     It should be recognized that the capability of performing the buffer management via the use of a semi-autonomous processor goes against the teaching of the art and initially was met with a great deal of skepticism. That is, since the foregoing described problems arise from a lack of synchronization between CDMA system clocks and PSTN system clocks, it was believed in the prior art that only a method and system tightly time-coupled to the primary digital signal processor would be able to provide the necessary control to solve the problems arising from the lack of synchronization. It was believed that the introduction of a semi-autonomous processor into such environment would create such a timing “wild-card” that the resulting system would prove unworkable given the tight timing constraints imposed by the nature of the problems arising from lack of synchronization between CDMA system clocks and PSTN system clocks. Consequently, the fact that the present invention worked (or solved the problems associated with lack of synchronization between CDMA system clocks and PSTN system clocks), and worked well, came as a complete surprise since the prior art taught away from the method and system of the present invention. 
     In addition to the foregoing, the prior art also taught away from the present invention in that one embodiment of the present invention modifies the size of the buffers in near real time. The prior art teaching and assumption was that the size of the buffers would always stay constant, and it was felt that real-time manipulation of buffer sizes would prove impractical. Consequently, the fact that the present invention worked (or solved the problems associated with lack of synchronization between CDMA system clocks and PSTN system clocks), and worked well, came as a complete surprise since the prior art taught away from the method and system of the present invention. An embodiment of the present invention will now be discussed. 
     One embodiment of the present invention is particularly applicable to the situation described in the background section, above. That is, the situation wherein a CDMA clock and a PSTN clock are not synchronized with each other, but in which each individual clock is relatively invariant when viewed in isolation. 
     Refer now to FIG.  2 . FIG. 2 depicts a system wherein one or more embodiments of the present invention may be practiced. Shown is CDMA voice coding subsystem  200 , which functions, from an overall systems standpoint, essentially in the same way as CDMA voice coding subsystem  100 . However, as can be seen in the figure, CDMA voice coding subsystem  200  has been internally modified such that it now contains semi-autonomous unit  202 . Further shown is that semi-autonomous unit  202  creates, controls, and communicates with two buffers: Buffer A  204  and Buffer B  206 . Semi-autonomous unit  202  communicates with Buffer A  204  and Buffer B  206  via data paths  203  and  205 , respectively. Shown also is that PCM-CDMA packet encoder  212  communicates with semi-autonomous unit  202  via communication link  208  and that PCM-CDMA packet encoder  212  has direct access to Buffer A  204  via data path  205 . Further shown is that semi-autonomous unit  202  receives PCM samples via PCM sample input stream  104 . 
     In the following discussion, Buffer B  206  will be treated as the working buffer, and as will be shown, the size of Buffer B  206  is dynamically varied in response to system parameters. This fact is illustrated via variable Buffer B boundary  207 . 
     For the sake of conceptual clarity, the following discussion will treat Buffer A  204  and Buffer B  206  “as if” Buffer A  204  and Buffer B  206  are “stationary” buffers from which the contents of one (Buffer B  206 ) will be transferred into the other (Buffer A  204 ). However, those skilled in the art will recognize that a preferred implementation of the buffers discussed would be to use what are known in the art as “circular buffers.” Consequently, where the following discussion speaks of “transferring,” or “loading,” the contents of Buffer B  206  into Buffer A  204 , it is to be understood that in the preferred embodiment such “transferring” would actually be implemented by communication between semi-autonomous unit  202  and PCM-CDMA packet encoder  212 , wherein ranges of pointers, or register addresses, would be exchanged such that the range of pointers defines Buffer A  204 . Furthermore, it will be understood by those within the art that concomitant changes would also be made internal to semi-autonomous unit  202  to the pointers which define, and delimit, Buffer B  206  such that the range of pointers would properly define Buffer B  206 . Since ranges of contiguous pointers, or register addresses, are utilized and subsequently reutilized to effect Buffer A  204  and Buffer B  206  it can be seen that the register addresses could be represented graphically as a circle; consequently, it is common within the art to refer to such created and managed buffers as “circular buffers.” 
     Due to the inherent complexity of the “circular buffer” scheme itself, it has been found more clear to discuss embodiments of the present invention as if “stationary” buffers were being utilized which can be read to and written from just “as if” they were fixed computer memory locations. However, it is to be borne in mind that the foregoing discussion, although couched in terms of fixed, or stationary, computer memory buffers, is in a preferred embodiment, implemented via the use of circular buffers by techniques well known to those within the art. 
     Refer now to FIG.  3 . FIG. 3 will be used in conjunction with FIG. 2 to illustrate an embodiment of the present invention which will alleviate the problems associated with a PCM input buffer, discussed in relation to FIG. 1 above. FIG. 3 constitutes a high-level logic flowchart which depicts an embodiment of the present invention. Method step  300  illustrates the start of the process, which is an entry point where DSP  210  is reset, and which equates to the “powering up” of CDMA voice coding subsystem  200 . 
     Method step  302  depicts that CDMA voice coding subsystem  200  creates working Buffer A  204  and storage Buffer B  206 , initially of equal size which in one embodiment equates to working Buffer A  204  and storage Buffer B  206  each being of a size capable of holding exactly PCM samples. 
     Method step  304  illustrates the initialization of an index which points to the start of storage Buffer B  206 . The index points to a register wherein one PCM data sample is stored. Each time PSTN clock  106  pulses, a PCM data sample is stored to a register of storage Buffer B  206 , and the index is incremented; thus, some offset of the index is possible should PSTN clock  106  pulses occur before a first ping of GPS clock  114  is received (that is, the index is being advanced even though PCM samples are not being stored to storage Buffer B  206 ). 
     Method step  306  shows an inquiry as to whether semi-autonomous unit  202  has received a signal correspondent to a first ping of GPS clock  114 . If no signal correspondent to a first ping of GPS clock  114  has been received, the process returns to method step  306 . However, if a signal correspondent to a first ping of a GPS clock  114  has been received, method step  308  depicts both that each PCM sample received on PCM input stream  204  by semi-autonomous unit  202  is loaded into storage Buffer B  206  and that the index pointing within storage Buffer B  206  is incremented (which will be done in time with the pulses of PSTN clock  106 ). 
     Method step  310  depicts that subsequent to the loading of a PCM sample into, and incrementing of the index pointing to, storage Buffer B  206 , a determination is made as to (1) whether the index pointing within storage Buffer B  206  indicates that the last register of the currently-set storage area of storage Buffer B  206  has been reached and loaded with data, or (2) whether a signal corresponding to a GPS clock  114  ping has been received. If neither condition is satisfied, the process proceeds to method step  308  and semi-autonomous unit  202  continues loading PCM samples into storage Buffer B  206 . However, in the event that either the last register of the currently-set storage area of storage Buffer B  206  has been reached and loaded with data, or a signal correspondent to a GPS clock  114  ping has been received, the process proceeds to method step  312 . 
     Method step  312  depicts that an inquiry is made as to whether the last register of the currently-set storage area of storage Buffer B  206  has been reached and loaded with data (i.e., is the index pointing at a register beyond the defined end of specified storage of storage Buffer B  206 ). In the event that the last register of the currently-set storage area of storage Buffer B  206  has been reached and loaded with data, the process proceeds to method step  314  wherein it is depicted that semi-autonomous unit  202  retrieves and augments (by either eliminating a number of the last samples in the data from storage Buffer B  206  if the number of samples is too great, or duplicating the last samples in the data from storage Buffer B  206  if the number of samples is too few) the contents of storage Buffer B  206  such that the total data block size is correct for working Buffer A  204  (it being understood that if the size of storage Buffer B  206  is the same as working Buffer A  204 , then no augmentation is necessary), and thereafter transfers the (possibly augmented) contents of storage Buffer B  206  into working Buffer A  204 . 
     Data having been transferred from storage Buffer B  206  into working Buffer A  204 , method step  316  illustrates that the index is set to the start of storage buffer B  206  so that it can be refilled. Thereafter, method step  318  indicates that DSP  210  is directed to start processing the working buffer and to utilize PCM-CDMA encoder  212  to encode the PCM data in working Buffer A  204  into a new CDMA packet. Thereafter, the process proceeds to method step  320 . 
     Returning to the inquiry of method step  312 , in the event that the last register of the currently-set storage area of storage Buffer B  206  has not been reached and loaded with data, the process proceeds to method step  320  which shows the determination as to whether a signal correspondent to a ping of GPS clock  114  has been received subsequent to that discussed in method step  310 . In the event that another signal correspondent to a ping of GPS clock  114  has not been received, the process returns to method step  308 . In the event that another signal correspondent to a ping of GPS clock  114  has been received, the process proceeds to method step  322 . 
     Method step  322  depicts that the current value of the index pointing within storage Buffer B  206  index is checked to see if the index is equal to the initialized value (recalling that the index is incremented every time a PCM sample is loaded into storage Buffer B, this the value to which it was set in method step  304 , provided that the index is set to “wrap,” or reset to the initial index value once the last buffer storage register of the currently-set storage area of storage Buffer B  206  has been used). If the index is equal to the initialized value, the process proceeds to method step  326  which illustrates that the defined storage area of storage Buffer B  206  is set to its original size. 
     If the index is not equal to the initialized value, then it is known that a slippage occurred and that the currently-set size of the storage area of storage Buffer B  206  is not correct, so method step  324  shows that the storage area of storage Buffer B  206  is changed so that it equates to the actual number of samples received between the last two signals correspondent to the last two GPS clock  114  pings; that is, the storage buffer is adjusted so that the index will hit its target value (i.e., there will be no slippage) when the next signal correspondent to ping of GPS clock B  114  is received—if the index is behind, the buffer size will be increased, and if the index is ahead, the buffer size will be decreased. 
     Refer now to FIG.  4 . FIG. 4 depicts a system wherein one or more embodiments of the present invention may be practiced. Shown is CDMA voice coding subsystem  400 , which functions, from an overall systems standpoint, essentially in the same way as CDMA voice coding subsystem  100 . However, as can be seen in the figure, CDMA voice coding subsystem  400  has been internally modified such that it now contains semi-autonomous unit  402 . Further shown is that semi-autonomous unit  402  creates, controls, and communicates with two buffers: Buffer A  404  and Buffer B  406 . Semi-autonomous unit  402  communicates with Buffer A  404  and Buffer B  406  via data paths  403  and  405 , respectively. Shown also is that CDMA packet-PCM sample decoder  420  communicates with semi-autonomous unit  202  via communication link  408  and that CDMA packet-PCM sample decoder  420  loads directly to Buffer A  404  via data path  405 . Further shown is that semi-autonomous unit  402  delivers PCM samples via data stream  409  to Buffer B  406 . Also shown is that Buffer B  406  feeds directly out onto PCM output stream  422 . 
     In the following discussion, Buffer B  406  will be treated as the working buffer, and as will be shown, the size of Buffer B  406  is dynamically varied in response to system parameters. This fact is illustrated via variable Buffer B  406  boundary  407 . 
     For the sake of conceptual clarity, the following discussion will treat Buffer A  404  and Buffer B  406  “as if” Buffer A  404  and Buffer B  406  are “stationary” buffers from which the contents of one (Buffer B  406 ) will be transferred into the other (Buffer A  404 ). However, those skilled in the art will recognize that a preferred implementation of the buffers discussed would be to use what are known in the art as “circular buffers.” Consequently, where the following discussion speaks of “transferring,” or “loading,” the contents of Buffer B  406  into Buffer A  404 , it is to be understood that in the preferred embodiment such “transferring” would actually be implemented by communication between semi-autonomous  402  unit and CDMA packet-PCM sample decoder  420 , wherein ranges of pointers, or register addresses, would be exchanged such that the range of pointers defines Buffer A  404 . Furthermore, it will be understood by those within the art that concomitant changes would also be made internal to semi-autonomous unit  402  to the pointers which defined, and the limit, Buffer B  406  such that the range of pointers would properly define Buffer B  406 . Since ranges of contiguous pointers, or register addresses are utilized and subsequently reutilized to effect Buffer A  404  and Buffer B  406  it can be seen that the register addresses could be represented graphically as a circle; consequently, it is common within the art to refer to such created and managed buffers as “circular buffers.” 
     Due to the complexity of the “circular buffer” scheme itself, it has been found most clear to discuss embodiments of the present invention as if “stationary” buffers were being utilized which can be read to and written from just “as it” they were fixed computer memory locations. However, it is to be borne in mind that the foregoing discussion, although couch to the terms of fixed computer memory buffers, is in a preferred embodiment, implemented via the use of circular buffers by techniques well known to those when the art. 
     Refer now to FIG.  5 . FIG. 5 will be used in conjunction with FIG. 4 to illustrate an embodiment of the present invention which will alleviate the problems associated with a PCM output buffer, discussed in relation to FIG. 1 above. FIG. 5 constitutes a high-level logic flowchart which depicts an embodiment of the present invention. Method step  500  illustrates the start of the process, which is an entry point where DSP  410  is reset, and which equates to the “powering up” of CDMA voice coding subsystem  400 . 
     Method step  402  depicts that CDMA voice coding subsystem  400  creates working Buffer A  404  and storage Buffer B  406 , initially of equal size which in one embodiment equates to working Buffer A  404  and storage Buffer B  406  each being of a size capable of holding exactly 160 PCM samples. 
     Method step  504  illustrates the initialization of an index which points to the start of storage Buffer B  406 . The index points to a register wherein one PCM data sample is stored. Each time PSTN clock  106  pulses, a PCM data sample is transferred out of a register of storage Buffer B  106 , and the index is incremented; thus, some offset of the index is possible should PSTN clock  106  pulses occur before a first ping of GPS clock  114  is received. 
     Method step  506  shows an inquiry as to whether semi-autonomous unit  402  has received a signal correspondent to a first ping of a GPS clock  114 . If no signal correspondent to a first ping of a GPS clock  114  has been received, the process returns to method step  506 . However, if a signal correspondent to a first ping of a GPS clock  114  has been received, method step  508  depicts both that (1) upon every PSTN clock  106  clock pulse, a PCM sample is transferred onto PCM output stream  122  from storage Buffer B  406  by semi-autonomous unit  402 , and (2) that the index pointing within storage Buffer B  206  is incremented (which will be done in time with the pulses of PSTN clock  106 ). That is, as storage buffer B  406  is emptied, the index is incrementing as the PCM samples are taken from working Buffer B  406  (that is, the index is being advanced even though PCM samples are not being transferred from storage Buffer B  406 ). 
     Method step  510  depicts that subsequent to the loading of a PCM sample out of, and incrementing of the index pointing to, storage Buffer B  406 , a determination is made as to (1) whether the index pointing within storage Buffer B  406  indicates that the last register of the currently-set storage area of storage Buffer B  406  has been reached and the data within that register transferred out of the register, or (2) whether a signal corresponding to a GPS clock  114  ping has been received. If neither condition is satisfied, the process proceeds to method step  508  and semi-autonomous unit  402  continues transferring PCM samples out of storage Buffer B  406 . However, in the event that either the last register of the currently-set storage area of storage Buffer B  206  has been reached and the data within that register transferred, or that a signal correspondent to a GPS clock  114  ping has been received, the process proceeds to method step  512 . 
     Method step  512  depicts that an inquiry is made as to whether the last register of the currently-set storage area of storage Buffer B  406  has been reached and the data therein transferred out (i.e., is the index pointing at a register beyond the defined end of specified storage of storage Buffer B  406 ). In the event that the last register of the currently-set storage area of storage Buffer B  406  has been reached and the data therein transferred out, the process proceeds to method step  514  wherein it is depicted that semi-autonomous unit  402  retrieves and augments (by either eliminating a number of the last samples in the data from storage Buffer B  406  if the number of samples is too great, or duplicating the last samples in the data from storage Buffer B  406  if the number of samples is too few) the contents of working Buffer A  404  such that the total data block size is correct for storage Buffer B  406  (it being understood that if the size of storage Buffer B  406  is the same as working Buffer A  404 , then no augmentation is necessary), and thereafter transfers the (possibly augmented) contents of working Buffer A  404  into storage Buffer B  406 . 
     Data having been transferred from working Buffer A  404  into storage Buffer B  406 , method step  516  illustrates that the index is set to the start of storage buffer B  406  so that it can be reemptied. Thereafter, method step  518  indicates that DSP  410  is to utilize CDMA packet-PCM sample decoder  420  to decode a CDMA packet and to place the decoded PCM samples into working Buffer A  404 . Thereafter, the process proceeds to method step  520 . 
     Returning to the inquiry of method step  512 , in the event that the last register of the currently-set storage area of storage Buffer B  406  has not been reached and the data therein transferred out, the process proceeds to method step  520  which shows the determination as to whether a signal correspondent to a ping of GPS clock  114  has been received subsequent to that discussed in method step  510 . In the event that another signal correspondent to a ping of GPS clock  114  has not been received, the process returns to method step  508 . In the event that another signal correspondent to a ping of GPS clock  114  has been received, the process proceeds to method step  522 . 
     Method step  522  depicts that the current value of the index pointing within storage Buffer B  406  index is checked to see if the index is equal to the initialized value (recalling that the index is incremented every time a PCM sample is transferred out of storage Buffer B  406 , this the value to which it was set in method step  504 , provided that the index is set to “wrap,” or reset to the initial index value once the last buffer storage register of the currently-set storage area of storage Buffer B  406  has been cleared). If the index is equal to the initialized value, the process proceeds to method step  526  which illustrates that the defined storage area of storage Buffer B  406  is set to its original size. 
     If the index is not equal to the initialized value, then it is known that a slippage occurred and that the currently-set size of the storage area of storage Buffer B  406  is not correct, so method step  524  shows that the storage area of storage Buffer B  406  is changed so that it equates to the actual number of samples received between the last two signals correspondent to the last two GPS clock  114  pings; that is, the storage buffer is adjusted so that the index will hit its target value (i.e., there will be no slippage) when the next signal correspondent to ping of GPS clock B  114  is received—if the index is behind, the buffer size will be increased, and if the index is ahead, the buffer size will be decreased. 
     While the invention has been particularly shown and described with reference to a preferred embodiment, it will be understood by those skilled in the art that various changes in form and detail may be made therein without departing from the spirit and scope of the invention.