Method and device for controlling a solenoid actuator

The invention claimed is: 1. A method of driving a solenoid actuator, the method comprising: connecting a voltage signal to the actuator and causing an electric current to flow through the actuator, the current having mutually different current intensities during temporally offset phases of actuator operation; selectively operating the actuator during a plurality of temporally subsequent closed-loop current control phases during which the current is maintained within a given target window defined between a lower current set point and an upper current set point, wherein the current through the actuator is measured and the voltage signal is adjusted to cause the current to remain within the given target window; selectively operating the actuator in a clamping phase between two respective closed-loop current control phases, during which clamping phase the current through the actuator is decreased by applying an inverted voltage signal to the actuator for a given clamping time period; measuring the current through the actuator immediately following the clamping phase to determine whether the current intensity has undershot or overshot the target window of the subsequent closed-loop current control phase; and generating a redefined clamping time period for a next following activation cycle by one of the following: if the current intensity has undershot the lower current set point of the target window, decreasing the given clamping time period by a defined unit of time; or if the current intensity has overshot the upper current set point of the target window, increasing the given clamping time period by a defined unit of time; or if the current intensity measured immediately following the clamping phase lies within the target window, retaining the given clamping time period as the redefined clamping time period; and operating the actuator in the next following activation cycle with the redefined clamping time period. 2. The method according to claim 1 , which comprises defining the defined unit of time as a smallest time amount available by a temporal resolution of an actuator control system and selectively increasing or decreasing the given clamping time period by the single smallest time amount for generating the redefined clamping time period. 3. The method according to claim 1 , which comprises, in addition to determining an undershoot or overshoot, measuring an amount of deviation of the current from the respective set point of the target window, and, in the step of generating the redefined clamping time period, selectively increasing or decreasing the redefined clamping time period by an amount that is proportional to the amount of deviation. 4. The method according to claim 1 , which comprises driving the actuator during the closed-loop current control phases by applying a pulse-width modulated (PWM) voltage signal to the actuator. 5. A circuit assembly for driving a solenoid actuator, a high side switch for connecting the actuator to a positive potential of a voltage supply and a low side switch for connecting the actuator to ground potential; wherein, when said high side switch and said low side switch are turned on, an electric current flows through the actuator from the positive voltage potential to ground potential; a sensor for measuring a current intensity of the electric current flowing through the actuator; a closed-loop control system for controlling the current flowing through the actuator during closed-loop current control phases in a closed-loop control scheme wherein the current intensity is driven in dependence on the current intensity measured by said sensor; a clamping control for decreasing the current flowing through the actuator during clamping phase during which said high side switch and said low side switch are disconnected and an electric current flows through the actuator with a negative voltage across the actuator; and a circuit responsive to a signal from said sensor and configured to adjust a time period for a subsequent clamping phase if a signal from said sensor indicates that the current intensity of the electric current flowing through the actuator immediately following a recently completed clamping phase falls outside a predetermined target window. 6. The circuit assembly according to claim 5 , wherein said circuit is an integrating circuit configured to adjust the time period by adding or subtracting a defined unit of time for each adjustment of the time period for the subsequent clamping phase. 7. The circuit assembly according to claim 5 , wherein said circuit is a proportional integral circuit configured to add or subtract an amount of time proportional to a deviation measured by said sensor for each adjustment of the time period for the subsequent clamping phase. 8. The circuit assembly according to claim 5 , wherein said circuit is configured to generate the adjusted time period for the subsequent clamping phase by one of the following: if the current intensity measured by said sensor has undershot a lower current set point of the target window, decreasing a given clamping time period for the subsequent clamping phase by a defined unit of time; or if the current intensity measured by said sensor has overshot an upper current set point of the target window, increasing the given clamping time period for the subsequent clamping phase by a defined unit of time; or if the current intensity measured immediately following the recently completed clamping phase lies within the target window, retaining the given clamping time for the subsequent clamping phase as the adjusted clamping time period. 9. The circuit assembly according to claim 8 , wherein the recently completed clamping phase and the closed-loop current control phases are in a first activation cycle and the subsequent clamping phase is in a second activation cycle immediately following the first activation cycle. 10. The circuit assembly according to claim 5 , wherein said current sensor is a shunt resistor connected between said low side switch and ground potential. 11. The circuit assembly according to claim 5 , wherein the recently completed clamping phase and the closed-loop current control phases are in a first activation cycle and the subsequent clamping phase is in a second activation cycle immediately following the first activation cycle. 12. A circuit assembly for driving a solenoid actuator, comprising: a high side switch for connecting the actuator to a positive potential of a voltage supply and a low side switch for connecting the actuator to ground potential, wherein when the high side switch and the low side switch are turned on, an electric current flows through the actuator in a first current path from the positive voltage potential to ground potential; a sensor coupled in the first current path and measuring a current intensity of the current flowing through the actuator; at least one clamping component coupled to the actuator so that the electric current flows through the actuator in a second current path to or from the ground potential during a clamping phase when the high side switch and the low side switch are turned off, the at least one clamping component decreasing the current flowing through the actuator during the clamping phase with a negative voltage across the actuator, with no current flowing through the sensor during the clamping phase; and a control system coupled to the high side switch and the low side switch for controlling activation of the high side and low side switches, the control system controlling the current flowing through the actuator during a succession of activation cycles in a closed-loop control scheme, each activation cycle