Device-controlled adaptive delay diversity

What is claimed is: 1. A communication device comprising: a communications subsystem having more than one transmit chains comprising at least a first transmit chain and a second transmit chain configurable to perform transmit diversity; and a controller communicatively coupled to the communications subsystem, and which: in response to determining a requirement to increase transmit power of an uplink signal that is more than an individual capacity of either one of the first and the second transmit chains: sequentially configures the first and the second transmit chains to transmit the uplink signal with one of: (i) cyclic delay diversity (CDD); or (ii) linear delay diversity (LDD) that delays the uplink signal transmitted by the second transmit chain with each of more than one phase shift or time delay values; transmits the uplink signal using transmit diversity with sequentially changed phase shift or time delay values for the one of CCD or LDD; monitors at least one of a direct measure and an indirect measure of uplink signal quality at a network node for each of the sequentially changed phase shift or time delay values; determines an optimal phase shift or time delay value for current channel conditions of the more than one phase shift or time delay values associated with a higher measure of uplink signal quality than other ones of the more than one phase shift or time delay values; and transmits the uplink signal via transmit diversity using the optimal phase shift or time delay value for the one of CDD or LDD. 2. The communication device of claim 1 , wherein the controller monitors the measure of uplink signal quality comprising a rate of transmit power control up bits received, via the communication subsystem, from the network node, wherein a lowest rate of transmit power control up bits indicates an optimum phase shift or time delay value. 3. The communication device of claim 2 , wherein the controller: sequentially increases or decreases the phase shift or time delay value; and in response to determining that the rate of receiving transmit power control up bits is increased, reverses a direction of sequentially changing the phase shift or time delay value to find the optimal phase shift or time delay value. 4. The communication device of claim 2 , wherein the controller determines a lower value and an upper value of a range of the more than one phase shift or time delay values based on resulting transmit power control up bits; cyclic prefix (CP) length; a number of resource block (RBs), a number of allocated subcarriers and subcarrier spacing received from the network node. 5. The communication device of claim 1 , wherein the controller: in response to a failure to identify an optimum phase shift or time delay value: transmits the uplink signal via transmit diversity using a previously determined optimal phase shift or time delay value for the one of CDD or LDD; sequentially increases or decreases the phase shift or time delay value from the previously determined optimal phase shift or time delay value; and in response to determining that a rate of receiving transmit power control up bits is increased, reverses a direction of sequentially changing the phase shift or time delay value to find a new optimal phase shift or time delay value. 6. The communication device of claim 1 , wherein the controller: compares a current measure of uplink signal quality with a quality threshold condition; and determines a current phase shift or time delay value to be an optimum phase shift or time delay value in response to the current measure of uplink signal quality satisfying the quality threshold condition. 7. The communication device of claim 1 , wherein the controller: monitors for one or more changing factors that affect channel conditions for CDD or LDD; and in response to detecting at least one of the one or more changing factors, restarts sequentially configuring the first and the second transmit chains to transmit the uplink signal with the one of CDD or LDD with each of more than one phase shift or time delay values to determine a new optimum phase shift or time delay value. 8. The communication device of claim 7 , wherein the one or more changing factors are among a group comprising: (i) device mobility speed; (ii) fading profile; (iii) operating frequency band; (iv) device operating region; (v) sensor-detected obstruction to uplink signal; (vi) radio access technology (RAT); (v) continuous transmit power control up bits; (vi) inability to decode transmit power control bits in a downlink from the network node; (vii) network allocation of one or more of size of resource block allocation and scheduling rate; and (viii) antenna correlation. 9. The communication device of claim 1 , wherein the controller: determines a rate of change of a channel environment between the communication device and the network device based on one or more of: (i) device mobility speed; and (ii) a rate of change in distance to the network device; and configures a time duration of sequentially configuring the phase shift or time delay value and monitoring the measure of uplink signal quality in relation to the rate of change. 10. A method comprising: configuring a communications subsystem of a communication device having more than one transmit chains comprising at least a first transmit chain and a second transmit chain to perform transmit diversity; and in response to determining a requirement to increase transmit power of an uplink signal, to a network device, that is more than an individual capacity of either one of the first and the second transmit chains: sequentially configuring the first and the second transmit chains to transmit the uplink signal with one of: (i) cyclic delay diversity; or (ii) linear delay diversity that delays the uplink signal transmitted by the second transmit chain with each of more than one phase shift or time delay values; transmitting the uplink signal using transmit diversity with sequentially changed phase shift or time delay values for the one of CDD or LDD; monitoring at least one of a direct measure and an indirect measure of uplink signal quality at a network node for each of the sequentially changed phase shift or time delay values; determining an optimal phase shift or time delay value for current channel conditions of the more than one phase shift or time delay value associated with a higher measure of uplink signal quality than other ones of the more than one phase shift or time delay values; and transmitting the uplink signal via transmit diversity using the optimal phase shift or time delay value for the one of CDD or LDD. 11. The method of claim 10 , further comprising monitoring the measure of uplink signal quality comprising a rate of transmit power control up bits received, via the communication subsystem, from the network node, wherein a lowest rate of transmit power control up bits indicates an optimum phase shift or time delay value. 12. The method of claim 11 , further comprising: sequentially increasing or decreasing the phase shift or time delay value; and in response to determining that the rate of receiving transmit power control up bits is increased, reversing a direction of sequentially changing the phase shift or time delay value to find the optimal phase shift or time delay value. 13. The method of claim 11 , further comprising determining a lower value and an upper value of a range of the more than one phase shift or time delay values based on resulting transmit power control up bits; cyclic prefix (CP) length; a number of resource block (RBs), a number of allocated subcarriers and subc