Hydrostatic transmission and method for braking using the same

What is claimed is: 1. A hydrostatic transmission for a traction drive, comprising: a primary unit coupled to an internal combustion engine of the traction drive; at least one secondary unit coupled to an output of the traction drive; two working lines of a closed circuit configured to fluidically connect the primary unit and the at least one secondary unit; an electrical control unit, wherein each of the primary unit and the at least one secondary unit have an adjustable pivot angle or an adjustable swept volume which are controllable by the electrical control unit during a braking operation of the hydrostatic transmission; and a P closed-loop controller configured for closed-loop control of a required total braking torque or of a value proportional to the required total braking torque, wherein an input variable of the P closed-loop controller is (i) a traveling speed difference between a setpoint traveling speed and an actual traveling speed, or (ii) a rotational speed difference, proportional to the traveling speed difference, between a setpoint rotational speed and an actual rotational speed of the at least one secondary unit, and wherein an output variable of the P closed-loop controller is a first additional braking torque of the at least one secondary unit or a first value, proportional to the first additional braking torque, of the at least one secondary unit. 2. The hydrostatic transmission according to claim 1 , further comprising: an operating element configured adjust the setpoint traveling speed or the setpoint rotational speed proportional to the setpoint traveling speed. 3. The hydrostatic transmission according to claim 1 , wherein the P closed-loop controller is a PI closed-loop controller. 4. The hydrostatic transmission according to claim 1 , wherein the P closed-loop controller is a PID closed-loop controller. 5. The hydrostatic transmission according to claim 1 , further comprising: a first pressure-limiting valve arranged on a first working line of the two working lines; and a second pressure-limiting valve arranged on a second working line of the two working lines, wherein the braking operation is a high-power braking operation in which a first part of the braking power is dissipated via one of the first and the second pressure-limiting valves, while a second part of the braking power is dissipated via the primary unit. 6. The hydrostatic transmission according to claim 5 , wherein the first and second pressure-limiting valves each have a flat characteristic curve with regard to their pressure difference as a function of their passed-through volume flow. 7. The hydrostatic transmission according to Claim 1 , wherein the first value proportional to the first additional braking torque is a first additional swept volume of the at least one secondary unit. 8. The hydrostatic transmission according to claim 7 , wherein the first additional swept volume is added to a minimum swept volume, giving a required total swept volume of the at least one secondary unit. 9. The hydrostatic transmission according to claim 1 , wherein the pivot angle and the swept volume of the primary unit are adjustable in both directions from a central position or from a zero position. 10. A hydrostatic transmission for a traction drive, comprising: a primary unit coupled to an internal combustion engine of the traction drive; at least one secondary unit coupled to an output of the traction drive; two working lines of a closed circuit configured to fluidically connect the primary unit and the at least one secondary unit; an electrical control unit, wherein each of the primary unit and the at least one secondary unit have an adjustable pivot angle or an adjustable swept volume which are controllable by the electrical control unit during a braking operation of the hydrostatic transmission; a P closed-loop controller configured for closed-loop control of a required total braking torque or of a value proportional to the required total braking torque; and a D closed-loop controller, wherein an input variable of the P closed-loop controller is (i) a traveling speed difference between a setpoint traveling speed and an actual traveling speed, or (ii) a rotational speed difference, proportional to the traveling speed difference, between a setpoint rotational speed and an actual rotational speed of the at least one secondary unit, and wherein an input variable of the D closed-loop controller is the setpoint traveling speed or the setpoint rotational speed proportional to the setpoint traveling speed. 11. The hydrostatic transmission according to claim 10 , wherein an output variable of the D closed-loop controller is a second additional braking torque of the at least one secondary unit or a second value, proportional to the second additional braking torque, of the secondary unit. 12. The hydrostatic transmission according to claim 11 , wherein the second value proportional to the second additional braking torque is a second additional swept volume of the secondary unit. 13. A method for closed-loop control of a required total braking torque or a required total swept volume, proportional to the required total braking torque, of a hydrostatic transmission for a traction drive, the method comprising: calculating a first additional swept volume with a P closed-loop controller based on a traveling speed difference or a rotational speed difference proportional to the traveling speed difference; adding the first additional swept volume to a minimum swept volume to give the required total swept volume of at least one secondary unit; and setting a swept volume of at least one secondary unit to the required total swept volume, wherein the hydrostatic transmission includes a primary unit coupled to an internal combustion engine of the traction drive, the at least one secondary unit coupled to an output of the traction drive, two working lines of a closed circuit configured to fluidically connect the primary unit and the at least one secondary unit, an electrical control unit, wherein each of the primary unit and the at least one secondary unit have an adjustable pivot angle or an adjustable swept volume which are controllable by the electrical control unit during a braking operation of the hydrostatic transmission, and the P closed-loop controller, wherein the P closed-loop controller is configured for closed-loop control of the required total braking torque or of a value proportional to the required total braking torque, and wherein an input variable of the P closed-loop controller is (i) the traveling speed difference between a setpoint traveling speed and an actual traveling speed, or (ii) the rotational speed difference, proportional to the traveling speed difference, between a setpoint rotational speed and an actual rotational speed of the at least one secondary unit. 14. The method according to claim 13 , further comprising: calculating a second additional swept volume with a D closed-loop controller based on the setpoint traveling speed or the setpoint rotational speed proportional to the setpoint traveling speed, wherein in adding the first additional swept volume, the second additional swept volume is jointly also added to the minimum swept volume of the at least one secondary unit.