Position determination using multi-subscription selective diversity

What is claimed is: 1. A method of determining a location of a wireless mobile device, comprising: determining, by the wireless mobile device, whether there is a preferred subscription for performing positioning operations of the wireless mobile device at a coarse location of the wireless mobile device, wherein the preferred subscription is one of a plurality of subscriptions associated with the wireless mobile device that provides a more accurate location of the wireless mobile device than remaining subscriptions of the plurality of subscriptions; and responsive to a determination that the preferred subscription for performing the positioning operations of the wireless mobile device at the coarse location of the wireless mobile device exists, utilizing, by the wireless mobile device, the preferred subscription for the positioning operations of the wireless mobile device. 2. The method of claim 1 , further comprising: determining, by the wireless mobile device, whether there is more than one candidate subscription of the plurality of subscriptions capable of performing a location-based service, responsive to a determination that more than one candidate subscription of the plurality of subscriptions capable of performing the location-based service exists, performing the determining, wherein the preferred subscription is one of the more than one candidate subscriptions. 3. The method of claim 1 , wherein the coarse location of the wireless mobile device is based on identities of cells serving the plurality of subscriptions. 4. The method of claim 1 , further comprising: responsive to a determination that the preferred subscription for performing the positioning operations of the wireless mobile device at the coarse location of the wireless mobile device does not exist: determining, at the wireless mobile device by a first subscription of the plurality of subscriptions, a first location of the wireless mobile device at the coarse location of the wireless mobile device; determining, at the wireless mobile device by a second subscription of the plurality of subscriptions, a second location of the wireless mobile device at the coarse location of the wireless mobile device; determining, by the wireless mobile device, whether the first location or the second location is more accurate; and responsive to a determination that the first location is more accurate than the second location, setting, by the wireless mobile device, the first subscription as the preferred subscription for the coarse location of the wireless mobile device. 5. The method of claim 4 , wherein setting the first subscription as the preferred subscription comprises storing an association between the coarse location and the first subscription. 6. The method of claim 1 , further comprising: responsive to a determination that the preferred subscription for performing positioning operations of the wireless mobile device at the coarse location of the wireless mobile device does not exist: receiving, at the wireless mobile device, first positioning assistance data for a first subscription of the plurality of subscriptions; receiving, at the wireless mobile device, second positioning assistance data for a second subscription of the plurality of subscriptions; comparing a first prediction of location accuracy provided by the first subscription to a second prediction of location accuracy provided by the second subscription; determining, by the wireless mobile device, whether the first prediction of location accuracy is higher than the second prediction of location accuracy; and responsive to a determination that the first prediction of location accuracy is higher than the second prediction of location accuracy, setting, by the wireless mobile device, the first subscription as the preferred subscription for the coarse location of the wireless mobile device. 7. The method of claim 6 , wherein a prediction of location accuracy comprises geometric dilution of precision (GDOP). 8. The method of claim 6 , wherein the first positioning assistance data comprises a first set of neighbor cells and the second positioning assistance data comprises a second set of neighbor cells, and wherein the comparing comprises: setting, by the first subscription, a first list of active neighbor cells to the first set of neighbor cells; setting, by the second subscription, a second list of active neighbor cells to the second set of neighbor cells; performing, by the first subscription, neighbor cell rejection based on the first list of active neighbor cells; performing, by the second subscription, neighbor cell rejection based on the second list of active neighbor cells; and determining, by the wireless mobile device, whether the first prediction of location accuracy is higher than the second prediction of location accuracy based on a first geographic distribution of neighbor cells in the first list of active neighbor cells compared to a second geographic distribution of neighbor cells in the second list of active neighbor cells. 9. The method of claim 8 , wherein performing the neighbor cell rejection is based on factors including neighbor cell response time, network synchronization, inter-frequency versus intra-frequency neighbor cell rejection, multipath resolution, or any combination thereof. 10. The method of claim 9 , wherein performing the neighbor cell rejection based on the neighbor cell response time comprises: removing neighbor cells from the first list of active neighbor cells that cannot be measured by the first subscription within a first response time provided in the first positioning assistance data; and removing neighbor cells from the second list of active neighbor cells that cannot be measured by the second subscription within a second response time provided in the second positioning assistance data. 11. The method of claim 9 , wherein performing the neighbor cell rejection based on the network synchronization comprises: removing neighbor cells from the first list of active neighbor cells that have misaligned position reference signals (PRS); and removing neighbor cells from the second list of active neighbor cells that have misaligned position reference signals (PRS). 12. The method of claim 9 , wherein performing the neighbor cell rejection based on the inter-frequency versus intra-frequency neighbor cell rejection comprises: removing inter-frequency neighbor cells and intra-frequency neighbor cells in the first list of active neighbor cells that are not on a same receive chain associated with the first subscription; and removing inter-frequency neighbor cells and intra-frequency neighbor cells in the second list of active neighbor cells that are not on a same receive chain associated with the second subscription. 13. The method of claim 9 , wherein performing the neighbor cell rejection based on the multipath resolution comprises: removing neighbor cells from the first list of active neighbor cells that have multipath greater than a first multipath threshold or multipath with channel bandwidth less than a first bandwidth threshold for multipath resolution; and removing neighbor cells from the second list of active neighbor cells that have multipath greater than a second multipath threshold or multipath with channel bandwidth less than a second bandwidth threshold for multipath resolution. 14. The method of claim 1 , further comprising: receiving, at the wireless mobile device, a location request from a network serving the wireless mobile device, wherein the wireless mobile device determines whether the preferred subscription exists, in response to th