System and method for closed loop uplink power control

We claim: 1. A node for optimizing uplink closed loop power control in a Radio Access Network (RAN) in which one or more base stations each service a plurality of mobile stations, the node configured to: at each base station, for each mobile station connected to the base station, determine a transmit power level for the mobile station's uplink transmissions, wherein the node is configured to determine the transmit power level by being configured to measure a current achieved signal to interference plus noise ratio (SINR) for each mobile station, and wherein each mobile station has a desired target SINR; update the desired target SINR for at least one of the plurality of mobile stations based on the current achieved SINR and prior SINR measurements to obtain a current desired target SINR; and for the at least one mobile station, adjust the transmit power level by sending a transmission power control (TPC) command to the mobile station based on a difference between the current desired target SINR and the current achieved SINR, wherein the node is further configured to: adaptively adjust the desired target SINR over time to ultimately approach a target SINR that is feasible, and determine if a rise in a measured interference level over a prior duration exceeds a threshold, and if so, the node being configured to maintain the desired target SINR. 2. The node of claim 1 , wherein the node is further configured to map the difference to a nearest entry in a set of possible TPC values. 3. The node of claim 1 , wherein the node is further configured to determine if the desired target SINR is feasible. 4. The node of claim 1 , wherein the node is further configured to determine if one or more mobile stations are progressing towards their desired target SINR. 5. The node of claim 1 , wherein the node is further configured provide a lower bound on the desired target SINR, wherein the lower bound is a SINR value required to support reliable communication with a lowest possible modulation and coding rate combination. 6. The node of claim 1 , wherein the node is further configured to determine if the current achieved SINR is close to the desired target SINR. 7. The node of claim 1 , wherein the node is further configured to provide an upper bound on the desired target SINR, wherein the upper bound is a SINR required to support a largest modulation and coding rate combination, or wherein the upper bound is adaptive over time and based on a largest anticipated modulation and coding parameter that would be used. 8. A node for optimizing uplink closed loop power control in a Radio Access Network (RAN) in which one or more base stations each service a plurality of mobile stations, the node configured to: at each base station, for each mobile station connected to the base station, determine a transmit power level for the mobile station's uplink transmissions, wherein the node is configured to determine the transmit power level by being configured to measure a current achieved signal to interference plus noise ratio (SINR) for each mobile station, and wherein each mobile station has a desired target SINR; update the desired target SINR for at least one of the plurality of mobile stations based on the current achieved SINR and prior SINR measurements to obtain a current desired target SINR; and for the at least one mobile station, adjust the transmit power level by sending a transmission power control (TPC) command to the mobile station based on a difference between the current desired target SINR and the current achieved SINR, wherein the node is further configured to: adaptively adjust the desired target SINR over time to ultimately approach a target SINR that is feasible, and reset the desired target SINR to a higher value, and transmit a TPC command to the at least one mobile station to cause its power level to increase, if determined interference levels are determined to have been reduced beyond a threshold level. 9. The node of claim 8 , wherein the node is further configured to map the difference to a nearest entry in a set of possible TPC values. 10. The node of claim 8 , wherein the node is further configured to determine if one or more mobile stations are progressing towards their desired target SINR. 11. The node of claim 8 , wherein the node is further configured provide a lower bound on the desired target SINR, wherein the lower bound is a SINR value required to support reliable communication with a lowest possible modulation and coding rate combination. 12. The node of claim 8 , wherein the node is further configured to provide an upper bound on the desired target SINR. 13. A node for optimizing uplink closed loop power control in a Radio Access Network (RAN) in which one or more base stations each service a plurality of mobile stations, the node configured to: at each base station, for each mobile station connected to the base station, determine a transmit power level for the mobile station's uplink transmissions, wherein the node is configured to determine the transmit power level by being configured to measure a current achieved signal to interference plus noise ratio (SINR) for each mobile station, and wherein each mobile station has a desired target SINR; update the desired target SINR for at least one of the plurality of mobile stations based on the current achieved SINR and prior SINR measurements to obtain a current desired target SINR; and for the at least one mobile station, adjust the transmit power level by sending a transmission power control (TPC) command to the mobile station based on a difference between the current desired target SINR and the current achieved SINR, wherein the node is further configured to: adaptively adjust the desired target SINR over time to ultimately approach a target SINR that is feasible, and periodically reset the desired target SINR to a value exceeding the current achieved SINR by a differential amount, whereby problems associated with increasing the desired target SINR based on a decrease in measured interference are at least substantially avoided. 14. The node of claim 13 , wherein the node is further configured to map the difference to a nearest entry in a set of possible TPC values. 15. The node of claim 13 , wherein the node is further configured to determine if the desired target SINR is feasible. 16. The node of claim 13 , wherein the node is further configured to determine if one or more mobile stations are progressing towards their desired target SINR. 17. The node of claim 13 , wherein the node is further configured provide a lower bound on the desired target SINR. 18. The node of claim 13 , wherein the node is further configured to provide an upper bound on the desired target SINR, wherein the upper bound is a SINR required to support a largest modulation and coding rate combination. 19. The node of claim 13 , wherein the node is further configured to provide an upper bound on the desired target SINR, wherein the upper bound is adaptive over time and based on a largest anticipated modulation and coding parameter that would be used, given payload information.