Hydrostatic drive system

What is claimed is: 1. A hydrostatic drive system for a machine comprising: a first hydraulic circuit including: a first variable displacement pump; and a first hydraulic motor configured to selectively receive a flow of pressurized hydraulic fluid from the first variable displacement pump at a first pressure; a second hydraulic circuit including: a second variable displacement pump; and a second hydraulic motor configured to selectively receive the flow of pressurized hydraulic fluid from the second variable displacement pump at a second pressure; and a controller configured to generate a single command signal directed to each of the first and second variable displacement pumps based on a pressure imbalance between the first pressure and the second pressure and to thereby increase the displacement of one of the first and second variable displacement pumps and decrease the displacement of the other of the first and second variable displacement pumps, the single command signal being indicative of an adjustment pressure by which one of the first pressure and second pressure is to be increased and the other of the first pressure and second pressure is to be decreased in order to maintain a pressure balance between the first and the second hydraulic circuits. 2. The hydrostatic drive system of claim 1 , wherein the first variable displacement pump includes a first swash plate connected to a first swash plate control valve, and wherein the controller uses the single command signal to output a first output control signal to a first solenoid valve associated with the first swash plate control valve. 3. The hydrostatic drive system of claim 2 , wherein the first solenoid valve is configured to adjust the first pressure based on the first output control signal. 4. The hydrostatic drive system of claim 1 , wherein the second variable displacement pump includes a second swash plate connected to a second swash plate control valve, and wherein the controller uses the single command signal to output a second control signal to a second solenoid valve associated with the second swash plate control valve. 5. The hydrostatic drive system of claim 4 , wherein the second solenoid valve is configured to adjust the second pressure based on the second output control signal. 6. The hydrostatic drive system of claim 1 , wherein the controller is configured to receive pressure signals from a first pressure sensor and a second pressure sensor provided on a first port and a second port of the first pump respectively, and wherein the pressure signals correspond to the first pressure in the first hydraulic circuit. 7. The hydrostatic drive system of claim 1 , wherein the controller is configured to receive a pressure signal from the third pressure sensor and the fourth pressure sensor provided on a first port and a second port of the second pump respectively, and wherein pressure signals correspond to the second pressure in the second hydraulic circuit. 8. The hydrostatic drive system of claim 1 , wherein the controller includes a proportional-integral (PI) controller having a proportional control and an integral control. 9. The hydrostatic drive system of claim 8 , wherein an integral gain factor associated with PI controller is configured to be maintained at a pre-determined value while the difference between the first pressure and the second pressure is greater than zero. 10. A machine comprising: ground engaging members disposed on a first side and a second side of the machine; a power source; and a hydrostatic drive system operatively coupling the power source to the ground engaging members, the hydrostatic drive system including: a first hydraulic circuit including: a first variable displacement pump; and a first hydraulic motor configured to selectively receive a flow of pressurized hydraulic fluid from the first variable displacement pump at a first pressure; a second hydraulic circuit including: a second variable displacement pump; and a second hydraulic motor configured to selectively receive the flow of pressurized hydraulic fluid from the second variable displacement pump at a second pressure; and a controller configured to generate a single command signal directed to each of the first and second variable displacement pumps based on a pressure imbalance between the first pressure and the second pressure and to thereby increase the displacement of one of the first and second variable displacement pumps and decrease the displacement of the other of the first and second variable displacement pumps, the single command signal being indicative of an adjustment pressure by which one of the first pressure and second pressure is to be increased and the other of the first pressure and second pressure is to be decreased in order to maintain a pressure balance between the first and the second hydraulic circuits. 11. The machine of claim 10 , wherein the first variable displacement pump includes a first swash plate connected to a first swash plate control valve, and wherein the controller uses the single command signal to output a first output control signal to a first solenoid valve associated with the first swash plate control valve. 12. The machine of claim 11 , wherein the first solenoid valve is configured to adjust the first pressure based on the first output control signal. 13. The machine of claim 10 , wherein the second variable displacement pump includes a second swash plate connected to a second swash plate control valve, and wherein the controller uses the single command signal to output a second control signal to a second solenoid valve associated with the second swash plate control valve. 14. The machine of claim 13 , wherein the second solenoid valve is configured to adjust the second pressure based on the second output control signal. 15. The machine of claim 10 , wherein the controller is configured to receive pressure signals from a first pressure sensor and a second pressure sensor provided on a first port and a second port of the first pump respectively, and wherein the pressure signals correspond to the first pressure in the first hydraulic circuit. 16. The machine of claim 10 , wherein the controller is configured to receive a pressure signal from the third pressure sensor and the fourth pressure sensor provided on a first port and a second port of the second pump respectively, and wherein pressure signals correspond to the second pressure in the second hydraulic circuit. 17. The machine of claim 10 , wherein the controller includes a proportional-integral (PI) controller having a proportional control and an integral control. 18. The machine of claim 17 , wherein an integral gain factor associated with PI controller is configured to be maintained at a pre-determined value while the difference between the first pressure and the second pressure is greater than zero. 19. A method for maintaining a pressure balance between a first hydraulic circuit having a first variable displacement pump and a second hydraulic circuit having a second variable displacement pump in a hydrostatic drive system, the method comprising: receiving pressure signals from a first pressure sensor and a second pressure sensor corresponding to a first pressure in the first hydraulic circuit; receiving pressure signals from a third pressure sensor and a fourth pressure sensor corresponding to a second pressure in the second hydraulic circuit; and controlling displacement of the first pump and the second pump by generating a single command signal directed to each of th