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A method and system for managing communication resources between nodes in a network, and more particularly to a dynamic distributed multi-channel time division multiple access (TDMA) slot assignment method is presented. The method and apparatus include a set of higher level heuristics that enable th

A method and system for managing communication resources between nodes in a network, and more particularly to a dynamic distributed multi-channel time division multiple access (TDMA) slot assignment method is presented. The method and apparatus include a set of higher level heuristics that enable the wireless channel access scheme to address predetermined characteristics of the wireless channel access system. These predetermined heuristics include using bootstrap slots, adaptive broadcast cycles, channelized neighborhoods, standby slots, speculation slots, neighbor segregation, hard circuits, and soft circuits.

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A method and system for managing communication resources between nodes in a network, and more particularly to a dynamic distributed multi-channel time division multiple access (TDMA) slot assignment method is presented. The method and apparatus include a set of higher level heuristics that enable th

A method and system for managing communication resources between nodes in a network, and more particularly to a dynamic distributed multi-channel time division multiple access (TDMA) slot assignment method is presented. The method and apparatus include a set of higher level heuristics that enable the wireless channel access scheme to address predetermined characteristics of the wireless channel access system. These predetermined heuristics include using bootstrap slots, adaptive broadcast cycles, channelized neighborhoods, standby slots, speculation slots, neighbor segregation, hard circuits, and soft circuits. 1. A method for optimizing the workload on connection sections given ABR traffic, comprising the steps of: transmitting ATM cells belonging to ABR traffic between a transmitter and a receiver via common connection sections, a forward transmission direction being thus defined; inserting control cells into a stream of said ATM cells that are taken by said receiver and returned to said transmitter, a return transmission direction being thus defined; measuring a frequency of occurrence of said ATM cells on a connection-associated basis during said transmission in said forward transmission direction, producing a measured result; measuring further, measured parameters; triggering a control procedure by said step of measuring a frequency of occurrence; supplying said measured frequency result to said control procedure together with said further, measured parameters, producing a calculated rate value; entering said calculated rate value by said control procedure into said control cells transmitted in said return transmission direction if said calculated rate value is greater than a rate value carried along in said control cells; and adapting a transmission rate in said transmitter to said rate value contained in said control cells if said rate value contained in said control cells is different from an original rate value stored in said transmitter. 2. A method according to claim 1, wherein: said further, measured parameters are direct, connection-associated parameters that comprise a measure for a current filling level of a waiting list, a current filling level of one of a plurality of scheduler blocks, as well as a current filling level of parameters calculated as a sum of said plurality of scheduler blocks. 3. A method according to claim 1, wherein: said further measured parameters are indirectly connection-associated parameters that comprise a measure for a monetary rate that a scheduler block has used for all the ABR connections of an appertaining scheduler block or a measure for a momentary rate that would be free for a sum of all ABR connections of said appertaining block. 4. A method according to claim 1, further comprising the step of: storing said measured result, together with said further, measured parameters in an input waiting list after said step of measuring said frequency of occurrence before said measured result and said further, measured parameters are supplied to said control procedure as input parameters. 5. A method according to claim 1, further comprising the steps of storing said calculated rate value in a first waiting list; subsequently converting said calculated rate value into an exponential format producing a converted calculated rate value; and entering said converted calculated rate value into said control cells. 6. A method according to claim 1, further comprising the step of briefly storing said ATM cells in a second waiting list during said step of measuring said frequency of occurrence. 7. A method according to claim 5, wherein said step of converting said calculated rate value further comprises the step of selecting a start value of e=9 for exponents that are greater than zero. 8. A method according to claim 5, wherein said step of converting said calculated rate value further comprises the step of supplying an exponent e and a mantissa M, wherein 0≤m≤512 and 2e(1+(m/512)) which corresponds to said calculated rate value. 9. A method according to claim 8, wherein said step of supplying an exponent e and a mantissa M, further comprises the step of incrementing e by 1 in steps for conversion of said calculated rate value that is higher than 1023, until the correct corresponding value of the exponent is reached. 10. A method according to claim 8, wherein said step of supplying an exponent e and a mantissa M, further comprises the step of decrementing e by 1 in steps for conversion of said calculated rate value that is lower than 512, until the correct corres