Flow estimation using hall-effect sensors and/or magnetic bearing currents

What is claimed is: 1. A blood circulation assist system, comprising: a blood pump comprising an impeller disposed within a blood flow channel of the blood pump and a motor stator operable to magnetically rotate the impeller, the impeller having an impeller axis of rotation around which the impeller is rotated, the motor stator being further operable to magnetically levitate the impeller within the blood flow channel transverse to the impeller axis of rotation; and a controller operatively coupled with the blood pump, the controller being configured to: determine an impeller rotational speed for the impeller; determine at least one impeller transverse position parameter based on at least one of (1) an amount of a bearing current that is used to levitate the impeller transverse to the impeller axis of rotation, and (2) a position of the impeller within the blood flow channel transverse to the impeller axis of rotation; and estimate a flow rate of blood through the blood pump based on the impeller rotational speed and the at least one impeller transverse position parameter. 2. The blood circulation assist system of claim 1 , wherein the controller is configured to: determine an amount of a drive current used to rotate the impeller; and estimate the flow rate based on the impeller rotational speed and the at least one impeller transverse position parameter when the amount of the drive current is above a drive current threshold. 3. The blood circulation assist system of claim 2 , wherein the drive current threshold varies based on the impeller rotational speed. 4. The blood circulation assist system of claim 2 , wherein the drive current threshold is based on characteristics of variation in the amount of bearing current used to levitate the impeller transverse to the impeller axis of rotation in response to variation in the impeller rotational speed. 5. The blood circulation assist system of claim 4 , wherein the drive current threshold is selected such that the amount of bearing current used to levitate the impeller transverse to the impeller axis increases in response to a decrease in the impeller rotational speed for drive currents above the drive current threshold. 6. The blood circulation assist system of claim 1 , wherein the controller is configured to: determine an amount of a drive current used to rotate the impeller; and estimate the flow rate based on the impeller rotational speed, the amount of the drive current, and the at least one impeller transverse position parameter when the amount of the drive current is within a drive current range. 7. The blood circulation assist system of claim 1 , wherein the impeller impels blood centrifugally and the blood pump outputs blood in a direction transverse to the impeller axis of rotation. 8. The blood circulation assist system of claim 1 , wherein the at least one impeller transverse position parameter is indicative of an amount of eccentricity of the impeller within the blood flow channel. 9. The blood circulation assist system of claim 1 , further comprising at least one sensor generating output indicative of the position of the impeller within the blood flow channel transverse to the impeller axis of rotation. 10. The blood circulation system of claim 9 , wherein the at least one sensor comprises a plurality of Hall sensors generating output indicative of the position of the impeller within the blood flow channel transverse to the impeller axis of rotation. 11. The blood circulation assist system of claim 1 , wherein the controller is configured to control the amount of a bearing current that is used to levitate the impeller transverse to the impeller axis of rotation so as to substantially minimize power consumption of the blood pump. 12. The blood circulation assist system of claim 1 , wherein the controller is configured to control eccentricity of the impeller within the blood flow channel so as to substantially minimize power consumption of the blood pump. 13. The blood circulation assist system of claim 12 , wherein the flow rate is estimated based on eccentricity of the impeller within the blood flow channel. 14. A blood circulation assist system, comprising: a blood pump comprising an impeller and a motor stator, the impeller being disposed within a blood flow channel of the blood pump and having an impeller axis of rotation around which the impeller is rotated, the motor stator comprising drive coils and levitation coils, driving current being applied to the drive coils to rotate the impeller around the impeller axis of rotation, bearing current being applied to the levitation coils to levitate the impeller transverse to the impeller axis of rotation; and a controller operatively coupled with the drive coils and the levitation coils, the controller being configured to control the bearing current so as to substantially minimize power consumption of the blood pump during operation of the blood pump comprising rotation of the impeller around the impeller axis of rotation. 15. The blood circulation assist system of claim 14 , wherein the controller comprises a bearing current controller that generates the bearing current based on a measured position of the impeller transverse to the impeller axis of rotation. 16. The blood circulation assist system of claim 15 , wherein the blood pump comprises Hall sensors that generate output indicative of the measured position of the impeller transverse to the impeller axis of rotation. 17. The blood circulation assist system of claim 15 , wherein the bearing current controller uses the bearing current as a feedback signal. 18. The blood circulation assist system of claim 15 , wherein the bearing current controller employs a three-level cascaded proportional-integral-derivative (PID) control method in which the measured position of the impeller transvers to the impeller axis of rotation and the bearing current are used as feedback signals. 19. The blood circulation assist system of claim 15 , wherein the bearing current controller is configured to control the position of the impeller transverse to the impeller axis in each of two separate directions.