Patent Document

BACKGROUND OF THE INVENTION 
     I. Field of the Invention 
     The present invention relates to a method and apparatus for controlling data transfer between two stations. 
     II. Description of the Related Art 
     IS-95 is an over-the-air interface standard which, together with its derivatives such as IS-95-A, IS-99 and IS-707, IS-657 and ANSI J-STD-008 etc. (referred to herein collectively as the IS-95 standards), defines an interface for implementing a digital personal communication system using code division multiple access (CDMA) signal processing techniques. A personal communication system configured substantially in accordance with the use of IS-95 is described in U.S. Pat. No. 5,103,459 entitled “System and Method for Generating Signal Waveforms in a CDMA Personal communication System” assigned to the assignee of the present invention and incorporated herein by reference. 
     FIG. 1 is a schematic diagram representing a personal communication system configured in accordance with IS-95. As is typical for most personal communication systems, IS-95 allows mobile telephone service to be provided to a set of wireless stations or terminals  10  (typically cellular telephones or “mobiles”) using a set of base transceiver stations (BTS)  12  coupled by a base station controller (BSC)  14  and a mobile switching center (MSC)  16  to a public switched telephone network (PSTN)  18 . During a call from a wireless terminal  10 , the terminal  10  interfaces with one or more base stations  12  in a communications link using CDMA modulated radio frequency (RF) signals. The RF signal transmitted from the base station  12  to the wireless terminal  10  is referred to as the forward link, and the RF signal transmitted from the wireless terminal  10  to the base station  12  is referred to as the reverse link. 
     Under the IS-99 and IS-707 standards (referred to hereinafter simply as IS-707), an IS-95 compliant communications system can also provide data communications services. Data communications services allow digital data to be exchanged using a wireless terminal  10  and the RF interface to one or more base stations  12 . Examples of the type of digital data typically transmitted using the IS-707 standard include computer files and electronic mail. Under IS-95A and IS-707, frames are transmitted once every 20 mS (milliseconds). 
     The IS-95B Standard has recently been developed to enable multiple traffic channels to be assigned to a wireless terminal by a base station in a communications link in both forward and reverse directions. IS-95B defines formats for supplemental traffic channels for different rate sets, but is silent as to how supplemental channels should be assigned in the communications link. There are only a finite number of traffic channels and, as such, the channels are a limited resource. Furthermore, it is not unusual in the transfer of data for the rate at which the data is delivered to vary with time. At some times the data rate may be relatively high and at others relatively low, the delay tolerances of several data sources is not rigid. It is wasteful of resources simply to assign a maximum number of channels to a communications link in order to ensure that the link is able to match the rate at which data is transferred with the maximum rate at which data may be delivered for transfer over the link. 
     The invention aims to overcome or at least minimize some of the above discussed disadvantages and problems. 
     The invention will be described in the following with reference to a CDMA system in which the invention may be embodied. A CDMA system is preferred because of the advantages that such a system offers over other communications systems. The invention is, however, not limited to being embodied in a CDMA system and can be applied equally to any communications system in which plural channels may be assigned in a communications link. 
     SUMMARY OF THE INVENTION 
     In one aspect the invention provides an apparatus for controlling data transfer between two stations, the apparatus comprising: a link manager for controlling allocation of available channels in a plurality of communications links in each of which communications links data is transferred between two stations in at least one channel; a data buffer for buffering data from a data source; and a controller for determining a parameter representing the buffering of data in the buffer and for generating a request for a change in the allocation of channels in a communications link between two stations depending on the parameter, and wherein the link manager is responsive to a request generated by the controller to allocate a different number of channels to the communications link or to generate a refusal of the request. 
     In another aspect the invention provides a method of controlling data transfer between two stations, the method comprising: controlling allocation of available channels in a plurality of communications links in each of which communications links data is transferred between two stations in at least one channel; buffering data from a data source; determining a parameter representing the buffering of data in the buffer; generating a request for a change in the allocation of channels in a communications link between two stations depending on the parameter; and responding to a generated request by allocating a different number of channels to the communications link or generating a refusal of the request. 
    
    
     BRIEF DESCRIPTION OF THE DRAWINGS 
     The above and further features of the invention are set forth with particularity in the appended claims and together with advantages thereof will become clearer from consideration of the following detailed description of an exemplary embodiment of the invention given with reference to the accompanying drawings. 
     In the drawings: 
     FIG. 1 is a schematic diagram representing a personal communication system, as already described herein above; 
     FIG. 2 is a schematic diagram representing a portion of a communications system embodying the invention; 
     FIG. 3 is a flow diagram showing a main sequence of operations performed by a supplemental channel controller in the system of FIG. 2; and 
     FIG. 4 shows a back off sequence of operations performed by the supplemental channel controller. 
    
    
     DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS 
     Referring now to FIG. 2 of the accompanying drawings, there is shown a portion of a communications system comprising a wireless terminal  10  (illustrated as a laptop computer and mobile telephone in combination). Operations that will be described in detail herein after may be performed either by one or more base transceiver stations  12  (BTS), or a base station controller  14  (BSC), or be distributed between both the one or more BTSs and the BCS. In order to simplify the following description a base transceiver station  12  and base station controller  14  are shown in FIG. 2 as a combined BSC/BTS controller  21 . A communications link comprising a forward link  22  and a reverse link  23  has been established between the terminal  10  and the controller  21 . 
     The controller  21  is connected to receive data from and transmit data to a data source/sink  24  via links  25 ,  26 . The links may be a local area network, or ordinary telephone or ISDN lines in a PSTN, and the data source/sink  24  may for example be a file server or the so-called Internet or World Wide Web. Typically the data from such a source is delivered in packets in uneven bursts. The controller  21  therefore comprises a TCP/IP or Point to Point Protocol (PPP) buffer  27  and a Radio Link Protocol (RLP) buffer  28 . The buffers  27 , 28  are used by software in the implementation of the TCP/IP, PPP, and RLP protocols. These protocols are well documented and are therefore well known and understood by those possessed of the appropriate skills. For example the RLP for a single code channel is defined in IS-707 and for multiple code channels in IS-707A. As such they need not be described in any greater detail herein. 
     Incoming data from the source  24  is buffered into the RLP buffer  28  and from there it is output onto the forward link  22  at a forward link service rate μ F  determined by a supplemental channel controller (SCC)  30 . The BSC/BTS  13  further comprises a radio link manager (RLM)  31  which manages the allocation of radio links (such as links  22  and  23 ) between each base transceiver station (BTS)  12  (see FIG. 1) and wireless terminals  10  that are currently communicating, or require to communicate, via the BTS. In response to requests from the supplemental channel controller  30  the radio link manager  31  allocates (or declines to allocate) additional or “supplemental” channels to augment data transfer between the BTS  12  and the wireless terminal  10 . 
     It should be noted that there will in fact be a separate PPP buffer  27 , RLP buffer  28  and supplemental channel controller (SCC)  30  for every data call (connection to/from a mobile) that the system is capable of establishing. The SCCs within the BSC operate independently of each other. That is to say, there is no direct interaction between them. In the interests of clarity, therefore, operation of only one SCC  30  will be described in detail in the following. It will of course be appreciated that other SCCs within the BSC/BTS  13  may be, in reality, executing the same operation at the same time. 
     The supplemental channel controller SCC  30  has stored within it various parameters which it uses to monitor the flow of data through the radio link protocol (RLP) buffer  28 . There are many ways in which the flow of data thorough the buffer may be measured. For example, the amount of data in the buffer (queue length), the rate at which data is arriving in the buffer, and the rate at which data is growing in the buffer are all indicators of data flow. The presently preferred measure is “latency”, which is a measure of the time taken for data to pass through the RLP buffer  28 . Latency is calculated by determining the amount of data in the RLP buffer  28  and dividing that amount by the rate at which data is being output from the RLP buffer  28  onto the forward link  22 . 
     The rate at which data is output, of course, depends on the number of channels that have been allocated to the link by the radio link manager  31 , and the latency is therefore a measure of whether the allocated channels are being usefully employed by the forward link  22 . The latency is compared to two thresholds, a high threshold (HI_threshold) and a low threshold (LO_threshold). These thresholds are preset at suitable values. For example, the high threshold may be set at 1 sec. and the low threshold at 0.2 sec. If the latency has a value between these thresholds then the allocated channels are deemed to be usefully employed. If the latency is greater than the high threshold, then there are insufficient channels allocated to the link. If the latency is less than the low threshold then the allocated channels are being under utilized by the link and may be more usefully employed elsewhere. 
     FIG. 3 of the accompanying drawings is a flow diagram showing a main sequence  33  of operations performed by the supplemental channel controller (SCC)  30  in monitoring the transfer of data from the source/sink  24  to the wireless terminal  10  and requesting the allocation of supplemental channels by the radio link manager (RLM)  31 . FIG. 4 of the accompanying drawings shows a back off routine  34  of operations performed by the supplemental channel controller (SCC)  30  in the event that a request is declined by the RLM  31 . Under IS-95A and IS-707, frames are transmitted once every 20 mS. The SCC  30  is therefore arranged to execute either the main routine  33  or the back off routine  34  every 20 mS, or a multiple thereof depending on wait states which are embedded in each of the routines  33 ,  34 . In FIGS. 3 and 4 elliptical blocks represent entry into or exit from the routine, square blocks represent actions performed by the routine, and hexagonal blocks represent decisions take within the routine. 
     The main routine will first be described with reference to FIG.  3 . The main routine is entered at block  35  and at block  36  the latency is calculated and compared to the high threshold. If the latency is less than the high threshold then the routine continues at block  37  by comparing the latency with the low threshold. If the latency is greater than the low threshold, then this means that the latency is within a range that is deemed acceptable and the allocated channels in the link are being usefully employed. 
     Under these conditions, the main routine continues at block  38  by looking at a low latency state hold timer (SC_timer) to see whether the timer is counting down. The conditions under which the SC timer is started will be described in detail herein below. For the moment it should be noted that the SC timer is included to avoid channels being unnecessarily “deallocated” and reallocated (i.e. released from the current data call for use in another data call) if the latency just momentarily falls below the low threshold. It takes time to deallocate and reallocate channels, typically 250 mS, and it would be wasteful of resources to do so repeatedly each time the latency moved out of range. The SC timer is arranged to measure a predetermined period of time, e.g. 1 sec., determined by the SC_timer counting 20 mS. time slots (1 sec. is equal to 50 such timeslots). If the SC counter is counting, then it is reinitialized and stopped at block  39 , because the conditions do not require any change in allocation. Otherwise the routine moves straight on to block  40  where it waits for a slot period (SLOT_TIME) (20 mS) before returning to reenter the main routine at block  35 . 
     In block  36  if the latency is found to be greater than the high threshold, then routine proceeds to block  41  where it again inspects the SC timer to see whether the timer is counting down. If the SC counter is counting, then it is reinitialized and stopped at block  42 , and the routine then moves on to block  43 . Otherwise, the routine moves straight on to block  43  where a request is sent by the supplemental channel controller (SCC)  30  to the radio link manager (RLM)  31  for further supplemental channels. The number of channels requested is calculated as the minimum of (1) the maximum number of supplemental channels that may be requested in a given request (NUM_REQ) and (2) the difference between the maximum allowed number of channels in the link (MAX_NUM_SUP) and the current number of allocated channels (current_NUM_SUP). As represented by block  44 , once the request has been sent the routine waits for the RLM  31  to respond to the SCC  30 . 
     In block  45 , when the RLM  31  responds, the routine determines how many of the requested channels have been allocated. If none of the requested channels have been allocated, then the routine enters the back off routine at block  46 . The back off routine is described in greater detail herein below with reference to FIG.  4 . If all or some of the requested channels have been allocated, then the routine waits for a period of time (ALLOC_TIME) and then reenters the main routine again at block  35 . ALLOC_TIME is defined as the minimum acceptable time between requests to allocate or deallocate supplemental channels, and conveniently may be set to, say, fifty time slots, i.e. 1 second. This wait is included to prevent the SCC  30  from requesting further channels too quickly after additional channels have been allocated to it. This also avoids the generation of control signals within the system that occurs when such requests are made. A rapid further allocation of channels may well be unnecessary, and the wait represented by block  47  avoids such a waste of resources from occurring. If no channels are allocated then the back off routine is entered at block  46 . The back off routine is described in detail herein below with reference to FIG.  4 . 
     Looking again at block  37 , if the latency is less than the low threshold, then this means that the latency is below a range in which the cost of maintaining all active supplemental channels is justifiable. The routine then continues by entering block  48  and looking at the value in the SC timer. If the SC counter is not counting down, then it is started at block  48  and the routine enters block  40  where it waits for a slot period, as previously described. Otherwise the value in the SC counter is decremented at block  50 . The SC counter value is then checked, as represented by block  51 , to determine whether it has yet reached zero. If the SC counter value has not reached zero, then the routine again returns to block  40 . However, if the value in the SC timer has reached zero, then this indicates that the latency has been less than the minimum deemed acceptable (LO_Threshold, e.g. 0.2 sec.) for a period of time determined by SC_timer, e.g. 1 sec. As represented by block  52 , the SCC will then request deallocation of a number of supplemental channels (NUM_SUP), i.e. the SCC  30  will notify the RLM  31  that the supplemental channels allocated to it are not being usefully employed. Then the SCC waits for a period of time equal to ALLOC_TIME, as represented by block  53  (see block  47 ) before reentering the main routine at block  35 . 
     The back off routine will now be described with reference to FIG.  4 . The back off routine is entered from the main routine at block  46  (see also FIG. 3) when no channels are allocated by the radio link manager (RLM)  31  in response to a request by the supplemental channel controller (SCC)  30 . On entry into the back off routine a counter (retry-attempt) is set to 1, as represented by block  55 . The SCC then waits for a period of time determined by WAIT_TIME (1 second) in block  56 . This is to allow the system to update system parameters, which could result in a change in the allocation requirements, before the SCC  30  sends another request to the RLM  31 . Next, in block  57 , a probability value p is calculated by dividing the latency by a predetermined maximum latency value (MAX_LATENCY). The maximum latency value is a period of time calculated from the size of the buffer (BUF_SIZE) and a fundamental rate. The fundamental rate depends on the rate set for the transfer of data in a channel and may have a value of 7950 bps (Rate_Set 1 ) or 13100 bps (Rate_Set 2 ). The maximum latency is calculated from the equation: 
     
       
         MAX_LATENCY=BUF_SIZE/FUNDAMENTAL_RATE. 
       
     
     Once the maximum latency is known the probability p can be calculated from the equation: 
     
       
           p =latency/MAX_LATENCY. 
       
     
     Next, as represented by block  58 , a trials counter (num_trials) is set to zero. In block  59  the latency is compared with the high threshold value. If the latency is less than the high threshold, then there is no longer a need to request supplemental channels because the latency has fallen to an acceptable level during the 1 second wait after the back off routine was entered. The SCC therefore exits the back off routine at block  35  by entering again the main routine. If, however, the latency is still higher than the high threshold, then a Bernoulli trial is performed at block  60 . A Bernoulli trial is equivalent to tossing a coin and gives a “yes”/“no” result on a random basis. Unlike a coin, however, the probability of a “yes” result is not 50%. Instead, the probability of the result of the Bernoulli trial being a “yes” is set equal to the probability value p. The higher the value of p, the more likely that the result of the trial will be a success, “yes”. The reason for this is to increase the likelihood of success if the need for supplemental channels is greater; i.e. the latency is high. A trials counter (num_trials) is also incremented at block  60 . 
     The result of the Bernoulli trial is examined at block  61 . If the trial has been unsuccessful, i.e. the result is a “no” (more likely if p is low), the trials counter is compared in block  63  with a predefined maximum number (MAX_NUM_TRIALS). The maximum number is conveniently 50, although other values may, of course, be chosen instead as appropriate. If the trial count is less than the maximum, then at block  64  the routine waits for a period of time calculated as the current value in the retry attempt counter (retry-attempt) multiplied by 20 mS., i.e. the period of one slot. The routine then returns to block  59  where the latency is again compared with the high threshold value. 
     If, however, the result of the Bernoulli trial is a success (“yes”) at block  61  or if the trial count equals the maximum at block  63 , then a request is sent at block  65  to the RLM for additional channels. The number of channels requested in block  65  is the same as the number requested in block  43  of FIG.  3 . As represented by block  66 , once the request has been sent the routine waits for the RLM  31  to respond to the SCC  30 . 
     In block  67 , when the RLM  31  responds, the routine determines how many of the requested channels have been allocated. If all or some of the requested channels have been allocated at block  66 , then the routine waits for the ALLOC_TIME (1 sec.) during block  68  and then reenters the main routine again at block  35 . This wait is included to prevent the SCC  30  from requesting further channels too quickly after additional channel have been allocated to it. A rapid further allocation of channels may well be unnecessary, and the wait represented by block  68  avoids such a waste of resources as well as unnecessary signaling from occurring. 
     If none of the requested channels have been allocated, then the routine again compares the latency with the high threshold at block  69 . If the latency has fallen below the high threshold, then there is no longer a need for further channels to be allocated and the back off routine returns to the main routine at block  35 . If, on the other hand, the latency is still higher than the high threshold (indicating that further channels are still required) then the attempt counter (retry_attempt) is incremented at block  70 . Then, as represented by block  71 , the attempt counter is compared with a predetermined maximum value (MAX_RETRY_COUNT). If the number of retries is equal to the maximum, then the main routine is reentered again at block  35 . Otherwise the routine returns to block  56  where it waits for 1 second (WAIT_TIME) before repeating the routine. 
     There are two effects at play during execution of the back off routine. On the one hand, when the value of p calculated at block  57  is high this will tend to increase the probability of a successful Bernoulli trial occurring, and thus reduce the time between which additional channel requests are made where the need for additional channels is greatest. On the other hand, the routine will steadily increase the time between requests (at block  64 ) after each retry attempt is made, until a maximum is reached (at block  71 ) when the back off routine returns to the main routine without any further channels having been allocated to the SCC by the RLM. 
     Having thus described the invention by reference to a preferred embodiment it is to be well understood that the embodiment in question is exemplary only and that modifications and variations such as will occur to those possessed of appropriate knowledge and skills may be made without departure from the spirit and scope of the invention as set forth in the appended claims and equivalents thereof.

Technology Category: 5