초록 ▼

A method and system determines an absolute Multicast-Broadcast Single Frequency Network (MBSFN) configuration based on a threshold. First saved radio resources and first wasted radio resources are calculated. The absolute MBSFN configuration is set as the final MBSFN configuration when the first sav

A method and system determines an absolute Multicast-Broadcast Single Frequency Network (MBSFN) configuration based on a threshold. First saved radio resources and first wasted radio resources are calculated. The absolute MBSFN configuration is set as the final MBSFN configuration when the first saved radio resources are greater than or equal to the first wasted radio resources. When untrue, the absolute MBSFN configuration plus an adjacent cell pool is set as the final MBSFN configuration based on the final MBSFN configuration achieving a maximum value of second saved radio resources minus second wasted radio resources. When both of these conditions are untrue, the absolute MBSFN configuration minus an MBSFN cell pool is set as the final MBSFN configuration based on the final MBSFN configuration achieving a maximum value of third saved radio resources minus third wasted radio resources.

대표청구항 ▼

1. A method of dynamic multicast-broadcast single frequency network (MBSFN) area configuration in consideration of radio resource efficiency comprising: determining a MBSFN configuration, the MBSFN configuration defining a number of users in a currently-defined MBSFN area and a number of idle guard

1. A method of dynamic multicast-broadcast single frequency network (MBSFN) area configuration in consideration of radio resource efficiency comprising: determining a MBSFN configuration, the MBSFN configuration defining a number of users in a currently-defined MBSFN area and a number of idle guard radio resources in an previously-defined MBSFN area, wherein the MBSFN configuration defines upper and lower thresholds of cell pool parameters;calculating first saved radio resources by multiplying the number of users in the currently-defined MBSFN area by a first weight factor;calculating first wasted radio resources by multiplying the number of idle guard radio resources in the previously-defined MBSFN area by a second weight factor;selecting all cell pools adjacent to the currently-defined MBSFN area in which cell pool parameters of the adjacent cell pools exceed the lower threshold of cell pool parameters when the first saved radio resources are less than the first wasted radio resources;selecting an adjacent cell pool from the adjacent cell pools such that second saved resources subtracted by second wasted resources achieves a maximum value when the adjacent cell pool is added to the MBSFN configuration, wherein the second saved resources are calculated by adding the number of users in the currently-defined MBSFN area to a number of new users in cells of the adjacent cell pool and multiplying by a third weight factor, andthe second wasted resources are calculated by adding the number of idle guard radio resources in the previously-defined MBSFN area to a number of idle guard radio resources in the cells of the adjacent cell pool and multiplying by a fourth weight factor; andsetting the cells of the adjacent cell pool and the MBSFN configuration as a MBSFN final configuration. 2. The method of claim 1, wherein the MBSFN configuration is determined utilizing at least one of a number of users or a Signal-to-Interference Noise-Ratio (SINR). 3. The method of claim 1, wherein the second weight factor is calculated by multiplying a number of potential users in the idle guard radio resources in the previously-defined MBSFN area by a wasted radio resource weight factor. 4. The method of claim 3, wherein the first weight factor is substantially equal to the wasted radio resource weight factor. 5. The method of claim 1, wherein the cell pool parameters comprise at least one of a number of users and a Signal-to-Interference Noise-Ratio (SINR). 6. The method of claim 1, wherein the first weight factor is substantially equal to the third weight factor. 7. The method of claim 1, wherein the second weight factor is substantially equal to the fourth weight factor. 8. The method of claim 1, further comprising: selecting all MBSFN cell pools within the currently-defined MBSFN area in which cell pool parameters of the MBSFN cell pools are below the upper threshold of cell pool parameters when the cell pool parameters of the adjacent cell pools are below the lower threshold of cell pool parameters or when none of the adjacent cell pools are such that the second saved radio resources are less than the second wasted radio resources;selecting an MBSFN cell pool from the MBSFN cell pools such that third saved resources subtracted by third wasted resources achieves a maximum value when the MBSFN cell pool is removed from the MBSFN configuration, wherein the third saved resources are calculated by subtracting the number of users in the currently-defined MBSFN area by a number of users in cells of the MBSFN cell pool and multiplying by a fifth weight factor, andthe third wasted resources are calculated by subtracting the number of idle guard radio resources in the currently-defined MBSFN area by a number of idle guard radio resources in the cells of the MBSFN cell pool and multiplying by a sixth weight factor; andsetting the cells of the MBSFN configuration minus the cells of the MBSFN cell pool as the MBSFN final configuration. 9. The method of claim 8, wherein the first weight factor is substantially equal to each of the third weight factor and the fifth weight factor. 10. The method of claim 8, wherein the second weight factor is substantially equal to each of the fourth weight factor and the sixth weight factor. 11. A dynamic Multicast-Broadcast Single Frequency Network (MBSFN) area configuration system for comparing saved radio resources with wasted radio resources to set a MBSFN final configuration, the system comprising: a core network for receiving data from multiple data sources;multiple radio network subsystems coupled to the core network, each of the radio network subsystems comprising multiple radio network controllers coupled to multiple base stations, the multiple base stations defining cells, wherein contiguous cells are grouped together to comprise an MBSFN area; anda number of user equipments (UEs) configured to receive MBSFN signals from the cells;an MBSFN configuration module for defining a MBSFN configuration, the MBSFN configuration defining a number of UEs in a currently-defined MBSFN area, a number of added idle guard radio resources in an previously-defined MBSFN area and an upper and lower threshold of cell pool parameters, wherein the MBSFN configuration module for calculating first saved radio resources among the saved radio resources by multiplying a first weight factor by the number of UEs in the currently-defined MBSFN area, calculate first wasted radio resources among the wasted radio resources by multiplying a second weight factor by the number of idle guard radio resources added to the previously-defined MBSFN area, select all cell pools adjacent to the currently-defined MBSFN area in which cell pool parameters of the adjacent cell pools exceed the lower threshold of cell pool parameters when the first saved radio resources are less than the first wasted radio resources, select an adjacent cell pool from the adjacent cell pools such that second saved radio resources among the saved radio resources subtracted by second wasted radio resources among the wasted radio resources achieves a maximum value when the adjacent cell pool is added to the MBSFN configuration, wherein the second saved radio resources are calculated by adding the number of UEs in the currently-defined MBSFN area to a number of new UEs in cells of the adjacent cell pool and multiplying by a third weight factor, and the second wasted radio resources are calculated by adding the number of idle guard radio resources in the previously-defined MBSFN area to a number of idle guard radio resources in the cells of the adjacent cell pool and multiplying by a fourth weight factor; andset the cells of the adjacent cell pool and the MBSFN configuration as the MBSFN final configuration. 12. The dynamic MBSFN area configuration system of claim 11, wherein the MBSFN configuration is determined utilizing at least one of a number of users or a Signal-to-Interference Noise-Ratio (SINR). 13. The dynamic MBSFN area configuration system of claim 11, wherein the second weight factor is calculated by multiplying a number of potential users in the idle guard radio resources in the previously-defined MBSFN area by a wasted radio resource weight factor. 14. The dynamic MBSFN area configuration system of claim 13, wherein the first weight factor is substantially equal to the wasted radio resource weight factor. 15. The dynamic MBSFN area configuration system of claim 11, wherein the first weight factor is substantially equal to the third weight factor. 16. The dynamic MBSFN area configuration system of claim 11, wherein the second weight factor is substantially equal to the fourth weight factor. 17. The dynamic MBSFN area configuration system of claim 11, wherein the MBSFN configuration module is further configured to: select all MBSFN cell pools within the currently-defined MBSFN area in which cell pool parameters of the MBSFN cell pools are below the upper threshold of cell pool parameters when the cell pool parameters of the adjacent cell pools are below the lower threshold of cell pool parameters or when none of the adjacent cell pools are such that the second saved radio resources are less than the second wasted radio resources;select an MBSFN cell pool from the MBSFN cell pools such that third saved radio resources among the saved radio resources subtracted by third wasted radio resources among the wasted radio resources achieves a maximum value when the MBSFN cell pool is removed from the MBSFN configuration, wherein the third saved radio resources are calculated by subtracting the number of UEs in the currently-defined MBSFN area by a number of UEs in cells of the MBSFN cell pool and multiplying by a fifth weight factor, andthe third wasted radio resources are calculated by subtracting the number of idle guard radio resources in the currently-defined MBSFN area by a number of idle guard radio resources in the cells of the MBSFN cell pool and multiplying by a sixth weight factor; andset the cells of the MBSFN configuration minus the cells of the MBSFN cell pool as the MBSFN final configuration. 18. The dynamic MBSFN area configuration system of claim 17, wherein the first weight factor is substantially equal to each of the third weight factor and the fifth weight factor. 19. The dynamic MBSFN area configuration system of claim 17, wherein the second weight factor is substantially equal to each of the fourth weight factor and the sixth weight factor.