Methods of efficiently sharing radio frequency (RF) resources in a dual SIM dual standby device

What is claimed is: 1. A method performed by a dual subscriber identification module (SIM) dual standby (DSDS) controller for efficiently sharing radio frequency (RF) resources in a DSDS device, the method comprising: receiving, when a data session is ongoing in a first SIM, a request from a second SIM for access to the RF resources for performing an activity at the second SIM having higher priority than the data session; determining a scaled throughput for the first SIM; determining an RF rejection percentage for the second SIM based on the scaled throughput; and providing the second SIM with access to the RF resources based on the RF rejection percentage. 2. The method of claim 1 , wherein the determining the scaled throughput includes considering one or more of: a load on a network side; a type of network being deployed; a direction of data transfer; a type of radio access technology (RAT) used by the first SIM; a mobility condition of the DSDS device; or a signal quality of other RATs. 3. The method of claim 2 , wherein the scaled throughput is determined based on an inverse term of the load on the network side. 4. The method of claim 1 , wherein the scaled throughput is determined based on a ratio of maximum bandwidth to a serving cell bandwidth. 5. The method of claim 1 , wherein the activity to be performed by the second SIM includes an activity belonging to a defined group of high priority activities. 6. The method of claim 5 , wherein the group of high priority activities includes at least one of: checking a paging channel; reading system information blocks; measuring a signal strength of a serving cell or neighbor cell; or establishing a packet switched data session. 7. The method of claim 1 , wherein the scaled throughput includes maximum of an uplink scaled throughput and a downlink scaled throughput. 8. The method of claim 1 , wherein determining the RF rejection percentage comprises: computing a reverse bell curve graph using the scaled throughput; and determining the RF rejection percentage for the second SIM based on the reverse bell curve graph. 9. The method of claim 1 , wherein determining the RF rejection percentage comprises: determining whether a signal quality of the second SIM is poor; reducing the RF rejection percentage for the second SIM by an offset value if the signal quality of the second SIM is poor; and increasing the RF rejection percentage for the second SIM by the offset value if the signal quality of the second SIM is good. 10. The method of claim 1 , wherein determining the RF rejection percentage comprises: determining a mobility condition of the DSDS device when the request for access to the RF resources is received from the second SIM; increasing the RF rejection percentage for the second SIM by an offset mobility value if the mobility condition of the DSDS device is stationary; and reducing the RF rejection percentage for the second SIM by the offset mobility value if the mobility condition of the DSDS device is mobile. 11. A dual subscriber identification module (SIM) dual standby (DSDS) device, the DSDS device comprising: a first SIM; a second SIM; RF resources; and a DSDS controller configured to receive, when a data session is ongoing in the first SIM, a request from the second SIM for access to the RF resources for performing an activity at the second SIM having higher priority than the data session; determine a scaled throughput for the first SIM; determine an RF rejection percentage for the second SIM based on the scaled throughput; and provide the RF resources to the second SIM based on the RF rejection percentage. 12. The DSDS device of claim 11 , wherein the scaled throughput is determined by considering one or more of: a load on a network side; a type of network being deployed; a direction of data transfer; a type of radio access technology (RAT) used by the first SIM; a mobility condition of the DSDS device; or a signal quality of other RATs. 13. The DSDS device of claim 12 , wherein the scaled throughput is determined based on an inverse term of the load on the network side. 14. The DSDS device of claim 11 , wherein the scaled throughput is determined based on a ratio of maximum bandwidth to a serving cell bandwidth. 15. The DSDS device of claim 11 , wherein the activity to be performed by the second SIM includes an activity belonging to a defined group of high priority activities. 16. The DSDS device of claim 15 , wherein the group of high priority activities includes at least one of: checking a paging channel; reading system information blocks; measuring a signal strength of a serving cell or neighbor cell; or establishing a packet switched data session. 17. The DSDS device of claim 11 , wherein the scaled throughput includes maximum of an uplink scaled throughput and a downlink scaled throughput. 18. The DSDS device of claim 11 , wherein the DSDS controller is further configured to: compute a reverse bell curve graph using the scaled throughput; and determine the RF rejection percentage for the second SIM based on the reverse bell curve graph. 19. The DSDS device of claim 11 , wherein the DSDS controller is further configured to: determine whether a signal quality of the second SIM is poor; reduce the RF rejection percentage for the second SIM by an offset value if the signal quality of the second SIM is poor; and increase the RF rejection percentage for the second SIM by the offset value if the signal quality of the second SIM is good. 20. The DSDS device of claim 11 , wherein the DSDS controller is further configured to: determine a mobility condition of the DSDS device when the request for access to the RF resources is received from the second SIM; increase the RF rejection percentage for the second SIM by an offset mobility value if the mobility condition of the DSDS device is stationary; and reduce the RF rejection percentage for the second SIM by the offset mobility value if the mobility condition of the DSDS device is mobile.