Systems and methods for controlling movement of drive units on a marine vessel

What is claimed is: 1. A method for controlling movement of drive units on a marine vessel, the marine vessel having a hull with a horizontally extending longitudinal axis and each drive unit having a respective vertically extending steering axis, the method being carried out by a control circuit and comprising: receiving an operator request for a desired steering angle; setting a steering angle of a first drive unit equal to the desired steering angle; determining a midpoint of a wetted surface area of the hull; defining a pivot line extending laterally through the midpoint and perpendicular to the longitudinal axis; determining a first intersection point of the pivot line and a line extending horizontally through the first drive unit's steering axis and parallel to the longitudinal axis; determining a second intersection point of the pivot line and a line representing perpendicular application of hydrodynamic force on the first drive unit; setting a steering angle of a second drive unit such that a line representing perpendicular application of hydrodynamic force on the second drive unit intersects the pivot line at the second intersection point; and sending control signals to actuate the first and second drive units to their respective steering angles. 2. The method of claim 1 , further comprising determining a speed of the marine vessel and inputting the speed of the marine vessel into a look-up table in order to obtain a calibrated estimate of the midpoint of the wetted surface area of the hull. 3. The method of claim 2 , wherein the midpoint of the wetted surface area of the hull moves toward a stern of the marine vessel as the speed of the marine vessel increases. 4. The method of claim 2 , wherein the first drive unit is more to an inside of a requested turn than the second drive unit, the inside of the requested turn being dictated by the desired steering angle. 5. The method of claim 4 , wherein an absolute value of the second drive unit's steering angle is less than an absolute value of the first drive unit's steering angle. 6. The method of claim 5 , wherein an amount by which the absolute value of the second drive unit's steering angle is less than the absolute value of the first drive unit's steering angle is directly proportional to the speed of the marine vessel. 7. The method of claim 1 , wherein the lines representing perpendicular application of hydrodynamic force on the respective first and second drive units are lines that extend perpendicular to skegs of the first and second drive units, respectively. 8. The method of claim 1 , further comprising sending control signals to actuate the first and second drive units in a same rotational direction in order to turn the marine vessel. 9. The method of claim 1 , further comprising setting steering angles of third and fourth drive units such that lines representing perpendicular application of hydrodynamic force on the third and fourth drive units, respectively, intersect the pivot line at the second intersection point; and sending control signals to actuate the third and fourth drive units to their respective steering angles. 10. A method for controlling movement of drive units on a marine vessel, the marine vessel having a hull with a horizontally extending longitudinal axis and each drive unit having a respective vertically extending steering axis, the method being carried out by a control circuit and comprising: receiving an operator request for a desired steering angle; defining one of the drive units as an inner drive unit based on the desired steering angle; setting a steering angle of the inner drive unit equal to the desired steering angle; determining a midpoint of a wetted surface area of the hull; defining a pivot line extending laterally through the midpoint and perpendicular to the longitudinal axis; calculating a first intersection point of the pivot line and a line extending horizontally through the inner drive unit's steering axis and parallel to the longitudinal axis; calculating an effective radius of rotation of the inner drive unit using the desired steering angle and a horizontal distance between the inner drive unit's steering axis and the first intersection point; calculating a steering angle for another drive unit using the inner drive unit's effective radius of rotation and a separation distance between the inner drive unit and the other drive unit; and sending control signals to actuate the inner drive unit and the other drive unit to their respective steering angles. 11. The method of claim 10 , further comprising calculating the inner drive unit's effective radius of rotation according to the equation R EI =D ST _ FI ÷tan (SA I ); wherein R EI is the inner drive unit's effective radius of rotation; D ST _ FI is the horizontal distance between the inner drive unit's steering axis and the first intersection point; and SA I is the inner drive unit's steering angle. 12. The method of claim 11 , wherein calculating the other drive unit's steering angle comprises determining if the desired steering angle is positive or negative. 13. The method of claim 12 , further comprising calculating the other drive unit's steering angle according to the equation SA 2 =arc tan (D ST _ FI ÷(R EI +D S )) when the desired steering angle is positive; wherein SA 2 is the other drive unit's steering angle; and D S is the separation distance between the inner drive unit and the other drive unit. 14. The method of claim 13 , further comprising calculating the other drive unit's steering angle according to the equation SA 2 =arc tan (D ST _ FI ÷(R EI −D S )) when the desired steering angle is negative. 15. The method of claim 13 , wherein the separation distance is a horizontal distance measured from the inner drive unit's steering axis to the other drive unit's steering axis. 16. The method of claim 10 , further comprising determining a speed of the marine vessel and inputting the speed of the marine vessel into a look-up table in order to obtain a calibrated estimate of the midpoint of the wetted surface area of the hull. 17. The method of claim 16 , wherein the midpoint of the wetted surface area of the hull moves toward a stern of the marine vessel as the speed of the marine vessel increases. 18. The method of claim 10 , wherein calculating the inner drive unit's effective radius of rotation comprises: calculating a second intersection point of the pivot line and a line representing perpendicular application of hydrodynamic force on the inner drive unit; and calculating a horizontal distance between the first intersection point and the second intersection point. 19. The method of claim 10 , further comprising sending control signals to actuate the inner drive unit and the other drive unit in a same rotational direction in order to turn the marine vessel. 20. The method of claim 10 , wherein an absolute value of the other drive unit's steering angle is less than an absolute value of the inner drive unit's steering angle.