Apparatus and methods for adaptive antenna diversity in a multi-antenna system

What is claimed is: 1. A method comprising: determining a signal quality metric using a first signal quality metric measurement for a primary antenna and a first diversity antenna having a first placement with respect to the primary antenna, and a second signal quality metric measurement for the primary antenna and a second diversity antenna having a second placement with respect to the primary antenna; comparing the determined signal quality metric to an inflection point threshold value, the inflection point threshold value determined from a relationship of signal-to-noise ratio and data throughput for each of at least two figure-of-merit types related to performance of the primary antenna when paired with one or the other of the at least two diversity antennas; determining a dominant figure of merit by determining a first figure-of-merit type as the dominant figure-of-merit if the determined signal quality metric is above the inflection point threshold value and a second figure-of-merit type as the dominant figure-of-merit if the determined signal quality metric is below the inflection point threshold value; and switching to one or the other of the at least two diversity antennas to prioritize the determined dominant figure-of-merit performance of the primary antenna when paired with one or the other of the at least two diversity antennas. 2. The method of claim 1 , wherein switching to one or the other of the at least two diversity antennas, comprises: switching to one of the at least two diversity antennas having a lower antenna correlation with the primary antenna when antenna correlation is the dominant figure of merit; and switching to another of the at least two diversity antennas having a lower gain imbalance with the primary antenna when gain imbalance is the dominant figure of merit. 3. The method of claim 1 , wherein determining the dominant figure-of-merit comprises: determining that antenna correlation is the dominant figure-of-merit when the signal quality metric is above the inflection point; and determining that gain imbalance is the dominant figure-of-merit when the signal quality metric is below the inflection point. 4. The method of claim 1 , further comprising: calculating the signal quality metric using signal-to-noise ratios obtained for each diversity antenna of the at least two diversity antennas. 5. A method comprising: calculating an effective signal quality metric using a first signal quality metric measurement for a primary antenna and a first diversity antenna having a first placement with respect to the primary antenna, and a second signal quality metric measurement for the primary antenna and a second diversity antenna having a second placement with respect to the primary antenna; and switching between the first diversity antenna and the second diversity antenna in response to the effective signal quality metric's relation to a threshold, the threshold indicating dominance of a first figure-of-merit type for values above the threshold and dominance of a second figure-of-merit type for values below the threshold. 6. The method of claim 5 , wherein calculating the effective signal quality metric, comprises: calculating an effective signal-to-noise ratio as the effective signal quality metric, the effective signal-to-noise ratio calculated using a first signal-to-noise ratio for the primary antenna and the first diversity antenna and a second signal-to-noise ratio for the primary antenna and the second diversity antenna. 7. The method of claim 6 , wherein switching between the first diversity antenna and the second diversity antenna in response to the effective signal quality metric's relation to the threshold, comprises: switching between the first diversity antenna and the second diversity antenna based on an inflection point in a relationship of signal-to-noise ratio and data throughput to the first figure-of-merit type and to the second figure-of-merit type, the inflection point being the threshold, wherein signal-to-noise ratio above the inflection point indicates selection of an antenna pair having lower antenna correlation with the primary antenna and wherein signal-to-noise ratio below the inflection point indicates selection of an antenna pair having lower gain imbalance with the primary antenna, wherein antenna correlation is the first figure-of-merit type and gain imbalance is the second figure-of-merit type. 8. The method of claim 5 , further comprising: predicting the effective signal quality metric based on a user history; and preselecting a diversity antenna in response to the prediction. 9. An apparatus comprising: at least one transceiver; a primary antenna; a first diversity antenna having a first placement with respect to the primary antenna; a second diversity antenna having a second placement with respect to the primary antenna; and antenna selection logic, operatively coupled to the primary antenna, the first diversity antenna, the second diversity antenna and the at least one transceiver, the antenna selection logic operative to: determine a signal quality metric using a first signal quality metric measurement for the primary antenna and the first diversity antenna, and a second signal quality metric measurement for the primary antenna and the second diversity antenna; compare the determined signal quality metric to an inflection point threshold value, the inflection point threshold value determined from a relationship of signal-to-noise ratio and data throughput for each of at least two figure-of-merit types related to performance of the primary antenna when paired with one or the other of the at least two diversity antennas; determine a dominant figure of merit by determining a first figure-of-merit type as the dominant figure-of-merit if the determined signal quality metric is above the inflection point threshold value and a second figure-of-merit type as the dominant figure-of-merit if the determined signal quality metric is below the inflection point threshold value; and switch to one or the other of the at least two diversity antennas to prioritize the determined dominant figure-of-merit performance of the primary antenna when paired with one or the other of the at least two diversity antennas. 10. The apparatus of claim 9 , wherein the antenna selection logic is further operative to: switch to one of the diversity antennas having a lower antenna correlation with the primary antenna when antenna correlation is the dominant figure of merit; and switch to another of the diversity antennas having a lower gain imbalance with the primary antenna when gain imbalance is the dominant figure of merit. 11. The apparatus of claim 9 , wherein the antenna selection logic is further operative to: determine that antenna correlation is the dominant figure-of-merit when the signal quality metric is above the inflection point; and determine that gain imbalance is the dominant figure-of-merit when the signal quality metric is below the inflection point. 12. The apparatus of claim 9 , wherein the antenna selection logic is further operative to: calculate the signal quality metric using signal-to-noise ratios obtained for each diversity antenna when paired with the primary antenna. 13. An apparatus comprising: at least one transceiver; a primary antenna; a first diversity antenna having a first orientation with respect to the primary antenna; a second diversity antenna having a second orientation with respect to the primary antenna; and antenna selection logic, operatively coupled to the primary antenna, the first diversity antenna, the second diversity antenna and the at lea