Abstract:
A retransmission value in a digital cellular phone is negotiated using information from the cellular phone, sent to the network.

Description:
BACKGROUND 
     In a digital telephone system, the mobile station (MS) and base station (BS) communicate with one another. A negative acknowledgement or “NAK” system is used by certain standards, e.g., IS 770, to allow the receiver of a signal to request retransmission if this signal was incorrectly received. For example, an incorrect reception can be detected by a cyclic redundancy code (CRC) that is transmitted with each packet of signals. 
     The receiver of the signals can be the mobile station or the base station. This receiver holds a number of packets of signals in memory. The receiver then orders the packets in the correct order, and decodes them. 
     If one or more signals in this group is faulty, the system may request that signal to be retransmitted. 
     The allowable number of retransmissions is set during a telephone setup. For example, this number may range between, only zero retransmissions, and ten retransmissions. The allowable number of transmissions effects the delay sensitivity and frame error rate. 
     The number of retransmissions affects many things. If the number of retransmissions is low, the memory requirements in the mobile station and/or the base station can be reduced. However, this makes it more likely that a received signal will be erroneous. Such errors can lower the quality of the communication. 
     SUMMARY 
     The present application teaches a technique allowing adaptive decision and determination of parameters in a digital telephone system. More specifically, the present application enables at least one of the communicating stations to adaptively set a transmission value based on conditions. This allows the mobile station to request a maximum number of retransmissions that is less than its maximum allowable value. 
     A system is disclosed in which the base station and mobile station negotiate to determine a maximum number of allowable retransmissions. This maximum number of retransmissions is based on at least conditions in the mobile station. 
    
    
     BRIEF DESCRIPTION OF THE DRAWINGS 
     These and other aspects will now be described in detail with respect to the accompanying drawings, wherein: 
     FIGS. 1A and 1B show a prior art system of negotiating and acknowledging the number of retransmissions; 
     FIG. 1C shows a flowchart of detecting transmission conditions; 
     FIGS. 2A and 2B show a first embodiment in which a first improvement is obtained by sending a value that is based on current conditions instead of its maximum value; 
     FIGS. 3A and 3B show a third embodiment in which multiple items of information are sent; and 
     FIG. 4 shows a system for a digital telephone with a base station and mobile station. 
    
    
     DETAILED DESCRIPTION 
     All of the systems herein operate with the telephone system of the general type shown in FIG.  4 . The mobile station  400  communicates with base station  450 . MS  400  includes a processor  402  which carries out the operations and flowcharts described herein. The telephone also includes a user interface  404 , as well as a display  401 , a cellular transceiver  406 . The processor communicates with memory  410 , as well as other associated peripherals, using conventional techniques. 
     The process of FIG. 1C can be carried out by the processor running a stored program. This program shows detecting information in the telephone that indicates a condition of the telephone that is related to an amount of loading on the telephone and/or its memory. 
     FIGS. 1A and 1B show the current NAK parameter negotiation between the mobile station and base station of the mobile communication network. In FIG. 1A, the system shows the current MO negotiation for the mobile station placing a call to the base station. Step  110  indicates the mobile station  400  sending an initial synchronization request to the base station. This initial synchronization request indicates the value MS_MAXIMUM; the number that the mobile station can support. The standard requires that this maximum be greater than or equal to 3. This information is received by the base station at  115 . The base station obtains a desirable retransmission figure BS_DESIRED. The base station sends the value BS_DESIRED to the mobile station at  120 . Note that BS_DESIRED value must be less than or equal to the MS_MAXIMUM value. BS_DESIRED is received by the mobile station at  125 . The mobile station then either accepts the base station&#39;s suggested value, or resets. A reset results in a failed call request. To accept the mobile station&#39;s request, the value of BS_DESIRED is repeated at  130 . This completes the negotiation. 
     An analogous operation is carried out for MT negotiation, in which an incoming call is received from the base station to the mobile station. Here, the base station sends its BS_DESIRED value to the mobile station at step  150 , received by the mobile station at  155 . The mobile station responds at  160  by sending a value indicating the maximum that the mobile station (MS_MAXIMUM) at step  160 . This value must be greater than 3. This is received by the base station at  165 . Then, at  170 , the base station sends its desired value, which is less than or equal to the maximum, to the mobile station. This is received at  180 . The mobile station accepts this value or resets. As above, the acceptance is indicated by repeating. 
     As can be seen, the base station and mobile station agree how many packets can be retransmitted. 
     The present application uses an improved system shown in FIG.  2 . This allows the mobile station to manage its own memory requirements and sets its own characteristics. This is done by allowing the mobile station to determine and specify a desired value, rather than its maximum value. 
     The operation is shown in FIG.  2 A. At step  200 , the mobile station sends its desired, not maximum, value MS_DESIRED to the base station. The base station received the value at  205 , and responds with a base station decision value BS_DECISION at  210 . This value must be less than the mobile station desired value. The mobile station receives this at  215 . The remaining steps of the process are similar to those discussed above in FIG.  1 A. 
     This operation enables the mobile station to have some input into its own memory requirements. 
     The mobile station can decide this maximum based on a number of different factors. An exemplary routine is shown in FIG.  1 C. 
     At step  190 , the routine selects a nominal memory value, which may represent the maximum memory value or some lesser value. The nominal memory value may be, for example, 6. 
     The system then decrements this memory value by a specified amount for each of a plurality of conditions that are found to be true. 
     The first step at step  191  is the detection that the previous call had a number of lost packets, i.e. more lost packets than n. When this is determined, it may be taken as an indication that the link is so bad that many lost packets may still exist no matter what happens. Therefore, at step  192 , the value of n is decreased. Note that FIG. 1C shows all of the values being decreased by the same amount. However a weighting factor can certainly be used to allow the different values to count more than other values. 
     At step  193 , the system determines that the available memory in the telephone is low. When this happens, the memory requirement is reduced at step  194 . 
     At step  195 , the system determines that the quality of service is low. This could happen, for example, if the user has paid for a lower quality of service or the like. Again, this can result in a reduction of memory requirements at step  196 . 
     Step  197  indicates a trend determination. The trend determination determines, from the time of day and other network parameters, whether is likely that the error rate will be high based on previous similar situations. If traffic is too high, then the user may lose packets in any case. This can therefore cause a reduction in the amount of desired memory at step  198 . 
     At step  240 , a situation is detected in which delay is critical. More retransmissions could cause a delay in the data signal. Therefore, if delay is critical, fewer retransmissions are made. 
     FIG. 2B shows the MT negotiation using “MS desired” parameter. In step  250  the base station recommends a value. The mobile station replies at step  252  with a desired value. The base station can use this value to make a decision less than the MS desired value. This can be accepted or rejected by the base station at step  255 . 
     This system allows the advantages of using mobile station information in making its decision. The base station usually has no information about the mobile station. However, in this situation, the base station obtains input from the mobile station as part of its negotiation, and before agreeing on a value. 
     FIG. 3A shows yet another situation where the mobile station sends both the desired and the maximum value to the base station, providing even more information for the negotiation. FIG. 3B shows the analogous situation in which the base station recommends and the mobile station responds with both a desired and maximum value. 
     Although only a few embodiments have been disclosed above other embodiments and modifications of the above are contemplated.