Brake system control unit and speed sensor arrangement

What is claimed is: 1. A control unit for controlling a brake system of a vehicle, the control unit comprising a receiver circuit configured to process, using at least one data processor, a digital signal from an active rotational speed sensor, the digital signal including (i) rotational speed information of a pole wheel disposed in front of the active rotational speed sensor and spaced from the active rotational speed sensor by an air gap, the pole wheel being configured to rotate with a wheel of the vehicle, and (ii) an actual air gap value representing the air gap between the pole wheel and the active rotational speed sensor, the actual air gap value being digitized in a plurality of stages and including a plurality of bits; a comparator circuit configured to compare, using at least one data processor, the actual air gap value with a setpoint air gap value and to determine whether the actual air gap value exceeds the setpoint air gap value by more than a tolerance value; and an information circuit configured to generate, using at least one data processor, pre-warning information when the comparator circuit determines that the actual air gap value exceeds the setpoint air gap value by more than the tolerance value, and output the pre-warning information to at least one of a brake controller and a warning light of the vehicle. 2. The control unit as claimed in claim 1 , wherein the comparator circuit is configured to compare the actual air gap value with a limiting air gap value and to determine whether the actual air gap value exceeds the limiting air gap value, and wherein the information circuit is configured to generate fault information when the comparator circuit determines that the actual air gap value exceeds the setpoint air gap value by more than the tolerance value and one of reaches and exceeds the limiting air gap value. 3. The control unit as claimed in claim 1 , wherein the comparator circuit is configured to compare the actual air gap value with one of a predefined air gap value and an interval between predefined air gap values and to determine that installation of the active rotational speed sensor is correct when the actual air gap value one of corresponds to the predefined air gap value and is in the interval between the predefined air gap values, and wherein the information circuit is configured to generate information as to whether the installation of the active rotational speed sensor is correct or not. 4. The control unit as claimed in claim 3 , further comprising an initialization circuit configured to set the setpoint air gap value to the actual air gap value when the installation of the active rotational speed sensor is correct; and a memory circuit for storing the setpoint air gap value. 5. A rotational speed sensor system, comprising: a) an active rotational speed sensor configured to (i) actively sense rotation of a pole wheel disposed in front of the active rotational speed sensor and spaced from the active rotational speed sensor by an air gap, and (ii) generate a digital signal including rotational speed information of the pole wheel, and an actual air gap value representing the air gap between the pole wheel and the active rotational speed sensor; b) the control unit as claimed in claim 1 ; and c) a data interface configured to transmit the digital signal from the active rotational speed sensor to the control unit. 6. The rotational speed sensor system as claimed in claim 5 , wherein the active rotational speed sensor includes: a) an active sensor element configured to actively sense the rotation of the pole wheel; b) an air gap-detection circuit configured to determine an analog measured value representing the air gap between the pole wheel and the active rotational speed sensor and to generate the actual air gap value by multi-stage digitization of the analog measured value; and c) a transmitter circuit to provide the digital signal. 7. The rotational speed sensor system as claimed in claim 5 , wherein the active rotational speed sensor is configured to be clamped in a securing opening in front of the pole wheel in at least one of a radial orientation and an axially displaceable orientation. 8. A vehicle brake system, comprising the control unit as claimed in claim 1 . 9. A vehicle, comprising the control unit as claimed in claim 1 . 10. A method for sensing rotational speed at a wheel of a vehicle, the method comprising: a) using an active rotational speed sensor to sense rotation of a pole wheel disposed in front of the active rotational speed sensor and spaced from the active rotational speed sensor by an air gap; b) by the active rotational speed sensor, providing a digital signal via a data interface to a control unit, the digital signal including rotational speed information of the pole wheel and an actual air gap value representing the air gap between the pole wheel and the active rotational speed sensor, the actual air gap value being digitized in a plurality of stages and including a plurality of bits; c) using a receiver circuit of the control unit to process, by at least one data processor, the digital signal; d) monitoring the air gap using a comparator circuit of the control unit configured to compare, by at least one data processor, the actual air gap value with a setpoint air gap value and to determine whether the actual air gap value exceeds the setpoint air gap value by more than a tolerance value; and e) using an information circuit of the control unit to generate, by at least one data processor, pre-warning information when the comparator circuit determines that the actual air gap value exceeds the setpoint air gap value by more than the tolerance value, and output the pre-warning information to at least one of a brake controller and a warning light of the vehicle. 11. The method as claimed in claim 10 , further comprising using the comparator circuit to compare the actual air gap value with a limiting air gap value and to determine whether the actual air gap value one of reaches and exceeds the limiting air gap value; and using the information circuit to generate fault information when the comparator circuit determines that the actual air gap value exceeds the setpoint air gap value by more than the tolerance value and one of reaches and exceeds the limiting air gap value. 12. The method as claimed in claim 10 , further comprising using the comparator circuit to compare the actual air gap value with one of a predefined air gap value and an interval between predefined air gap values and to determine that installation of the active rotational speed sensor is correct when the actual air gap value one of corresponds to the predefined air gap value and is in the interval between the predefined air gap values; and using the information circuit to generate information as to whether the installation of the active rotational speed sensor is correct or not. 13. The method as claimed in claims 10 to 12 , further comprising using an initialization circuit of the control unit to set the setpoint air gap value to the actual air gap value when the installation of the active rotational speed sensor is correct; and using a memory circuit of the control unit to store the setpoint air gap value. 14. The method as claimed in claim 10 , further comprising using an active sensor element of the active rotational speed sensor to actively sense rotation of the pole wheel; using an air gap detection circuit of the active rotational speed sensor to determine an analog measured value representing the current air gap between the pole wheel and the active rotational speed sensor and to generate the actual air gap va