Axial flow pump pressure algorithm

The invention claimed is: 1. An implantable blood pump system comprising: a pump including a housing having an axis, and a rotor disposed within the housing, the rotor being rotatable around the axis; and a control circuit operatively coupled to the pump, the control circuit being configured to: determine a flow rate of blood based at least in part on a parameter related to thrust on the rotor along the axis; and determine a pressure condition of the pump based at least in part on the flow rate of blood, the pressure condition being a condition under which differential pressure across the pump equals or exceeds a threshold pressure value. 2. An implantable blood pump system as in claim 1 , wherein the pump includes a stator operatively coupled to the control circuit, the stator incorporating a plurality of coils for applying a rotating magnetic field to the rotor. 3. An implantable blood pump system as in claim 2 , wherein the parameter is based on back electromotive force (BEMF) in one or more of the plurality of coils. 4. An implantable blood pump system as in claim 1 , wherein the control circuit includes a processor coupled to a memory, the memory storing a table that relates flow rates to corresponding amounts of differential pressure at the blood pump. 5. An implantable blood pump system as in claim 1 wherein the control circuit is operative to determine the differential pressure based on the flow rate and speed of rotation of the rotor. 6. A control circuit for monitoring the operation of an implantable blood pump, the control circuit comprising: a flow rate determination circuit operative to determine a flow rate of blood based at least in part on a parameter related to thrust generated by a rotor of the pump; and a pump pressure condition determination circuit operative to determine a pressure condition of the pump based at least in part on the determined flow rate of blood, the pressure condition being a condition under which differential pressure across the pump equals or exceeds a threshold pressure value. 7. A control circuit as in claim 6 , wherein the pump pressure condition determination circuit is operative to determine the pressure condition of the pump based on the flow rate and speed of rotation of the rotor. 8. A control circuit as in claim 6 , wherein the parameter is related to back electromotive force (BEMF) in a coil of the pump. 9. A control circuit as in claim 8 , wherein: the control circuit is operable to sample voltage across a first coil of a stator of the pump during an open-phase period in which: (i) the first coil is not being driven, and (ii) at least one other coil in the stator is being driven; so as to evaluate a function of back electromotive force (BEMF) during the open-phase period, wherein the flow rate is determined based at least in part on the function of BEMF and speed of rotation of the rotor. 10. A control circuit as in claim 9 , wherein the function of BEMF is a rate of change of the BEMF. 11. A control circuit as in claim 6 , further comprising: a processor; and a memory coupled to the processor, the memory storing a table that relates different flow rates to different amounts of differential pressure at the blood pump for a given speed of rotation of the rotor. 12. A control circuit as in claim 6 , further comprising a pump control module operative to control operation of the pump based at least in part on the determined pressure condition. 13. A method for monitoring operation of an implantable blood pump, the method comprising: determining a flow rate of blood through the pump, wherein the flow rate is determined based at least in part on (i) a parameter relating to thrust generated by a rotor of the pump and (ii) speed of rotation of a rotor of the pump; and determining a pressure condition of the pump based at least in part on the flow rate of blood, the pressure condition being a condition under which differential pressure across the pump equals or exceeds a threshold pressure value. 14. A method as in claim 13 , further comprising: sampling voltage across a first coil in the stator during an open-phase period in which: (i) the first coil is not being driven, and (ii) at least one other coil in the stator is being driven; and evaluating a function of back electromotive force (BEMF) during the open-phase period, wherein the flow rate is determined based on the function of BEMF and speed of rotation of the rotor; and determining the speed of rotation of the rotor based on the sampled voltage. 15. A method as in claim 14 , further comprising determining the flow rate of blood through the pump based at least in part on the magnitude of a current supplied to the pump. 16. A method as in claim 14 , wherein the function of BEMF is a rate of change of BEMF. 17. A method as in claim 13 , further comprising controlling the operation of the pump based on the determined pressure condition. 18. An implantable blood pump system comprising: a pump including a housing having an axis, and a rotor disposed within the housing, the rotor being rotatable around the axis; and a control circuit operatively coupled to the pump, the control circuit being configured to: determine a differential pressure across the blood pump based at least in part on an initial speed of rotation of the rotor; compare the differential pressure to a threshold pressure value; determine the presence or absence of a high pressure condition based at least in part on the comparison; and in response to determining the presence of a high pressure condition, determine an updated speed of rotation of the rotor, the updated speed being less than the initial speed. 19. An implantable blood pump system as in claim 18 , wherein the control circuit is operative to determine differential pressure based further on a flow rate of blood. 20. An implantable blood pump system as in claim 18 , the control circuit further including a pump control module operative to control operation of the pump based on the updated determined speed. 21. An implantable blood pump system as in claim 18 , the control circuit further including a processor coupled to a memory, the memory storing one or more tables, the one or more tables relating flow rates to corresponding differential pressure values for a given speed of rotation of the rotor, wherein at least one table relates flow rates to differential pressure values at the initial speed. 22. An implantable blood pump system as in claim 18 , wherein the control circuit is operative to determine the updated speed based on the speed of the rotor at which the presence of a high pressure condition is determined. 23. An implantable blood pump system as in claim 18 , wherein the control circuit is further operative to: determine differential pressure across the blood pump at the updated speed; and delay determination of the differential pressure at the updated speed for a predetermined amount of time based on a count value indicative of a number of recovery attempts initiated. 24. A control circuit for monitoring the operation of an implantable blood pump, the control circuit comprising: a differential pressure determination circuit operative to determine an amount of differential pressure across the blood pump; a pressure condition determination circuit operative to determine whether the determined amount of differential pressure is at least equal to a differential threshold pressure value; and