Method for monitoring an implementation of an automatedly demanded braking preset, and brake system

The invention claimed is: 1. A method for monitoring an implementation of an assistance braking specification, requested in an automated fashion, by a brake system comprising an ABS brake system, in a vehicle comprising a utility vehicle, having at least the following steps: detecting whether an assistance braking specification which is requested in an automated fashion is present; detecting an actual dynamics variable, the actual dynamics variable comprising wheel dynamics of at least one wheel of the vehicle and/or of a trailer, the actual dynamics variable being assigned to a wheel which is to be braked as a result of the assistance braking specification which is requested in an automated fashion; determining a reference dynamics variable, the reference dynamics variable comprising driving dynamics of the vehicle and/or of the trailer; and comparing the actual dynamics variable with the reference dynamics variable, wherein when an assistance braking specification is present: a faultfree implementation of the assistance braking specification which is requested in an automated fashion is detected if the actual dynamics variable deviates, taking into account a noise deviation, at least temporarily from the reference dynamics variable by a pulse deviation, and/or a faulty implementation of this assistance braking specification which is requested in an automated fashion is detected if the actual dynamics variable does not deviate, taking into account the noise deviation, from the reference dynamics variable by a pulse deviation. 2. The method as claimed in claim 1 , wherein the actual dynamics variable is determined on an axle basis and/or on a wheel basis. 3. The method as claimed in claim 1 , wherein the actual dynamics variable comprises an actual wheel acceleration or an actual wheel speed of a respective wheel of the vehicle or of the trailer, wherein the actual wheel acceleration is determined from actual wheel speeds of the respective wheel, and wherein the actual wheel speeds specify current wheel dynamics of the respective wheel. 4. The method as claimed in claim 3 , wherein the actual wheel acceleration follows from the actual wheel speeds by a mathematical derivation. 5. The method as claimed claim 1 , wherein the reference dynamics variable is specified by a current vehicle actual acceleration and/or a current vehicle actual speed and/or a mean value of the actual dynamics variable plotted against time. 6. The method as claimed claim 1 , wherein the noise deviation specifies noise in the measurement variables which characterize the wheel dynamics. 7. The method as claimed claim 1 , wherein the pulse deviation corresponds at least to the noise deviation. 8. The method as claimed claim 7 , wherein the pulse deviation corresponds at least to twice the noise deviation. 9. The method as claimed claim 1 , wherein, to implement the assistance braking specification which is requested in an automated fashion, a service-brake brake pressure at service brakes at the respective wheels of the vehicle and/or of the trailer is increased incrementally. 10. The method as claimed in claim 9 , further comprising determining whether a pulse deviation occurs at the respective wheel owing to the incremental increasing of the service-brake brake pressure, the pulse deviation being dependent on a magnitude of the service-brake brake pressure. 11. The method as claimed in claim 10 , wherein the pulse deviation becomes greater as the service-brake brake pressure rises. 12. The method as claimed in claim 10 , wherein the incremental increasing of the service-brake brake pressure takes place: at the service brakes of the vehicle by actuating ABS control valves, and/or at service brakes of the trailer by actuating the pressure control valve, and by switching a switching valve from a first switching-valve switched position into a second switching-valve switched position in which a multi-purpose pressure medium is released from a multi-purpose pressure medium reservoir. 13. The method as claimed in claim 12 , further comprising, if no faultfree implementation of the assistance braking specification has been detected, inferring that there is a mechanical defect in the switching valve and/or in the pressure control valve and/or in the ABS control valves; and outputting a warning signal and/or an assistance braking specification which has been requested in an automated fashion is aborted. 14. The method as claimed claim 1 , wherein when an assistance braking specification is present, a faultfree or faulty implementation of this assistance braking specification which is requested in an automated fashion is detected by comparing the actual dynamics variable with the reference dynamics variable, without having recourse to a pressure sensor. 15. A brake system comprising ABS brake system, for a vehicle, comprising a utility vehicle, the brake system comprising: a service brake valve configured to receive a service-brake braking specification; at least one relay valve which is assigned to a vehicle axis of the vehicle and is configured to output a service-brake brake pressure to service brakes of the vehicle; a switching valve which is connected upstream of the at least one relay valve, in a first switching-valve switched position the switching valve being configured to pass on a service-brake control pressure, which is output by the service brake valve as a function of the service-brake braking specification to the at least one relay valve in order to output the service-brake brake pressure by the at least one relay valve as a function of the service-brake control pressure, and in a second switching-valve switched position the switching valve being configured to connect a pressure medium reservoir to the relay valve in order to output a service-brake brake pressure by the at least one relay valve as a function of a multi-purpose pressure medium pressure in the multi-purpose pressure medium reservoir; ABS control valves which are connected upstream of the service brakes and are configured to adapt the service-brake brake pressure, which is output by the at least relay valve; and a central module configured to control the ABS control valves and the switching valve and to carry out a method for adapting the service-brake brake pressure, which is output by the at least one relay valve, as a function of the current assistance braking specification, the method for adapting the service-brake pressure comprising: detecting whether an assistance braking specification which is requested in an automated fashion is present; detecting an actual dynamics variable, the actual dynamics variable comprising wheel dynamics of at least one wheel of the vehicle and/or of a trailer, the actual dynamics variable being assigned to a wheel which is to be braked as a result of the assistance braking specification which is requested in an automated fashion; determining a reference dynamics variable, the reference dynamics variable comprising driving dynamics of the vehicle and/or of the trailer; and comparing the actual dynamics variable with the reference dynamics variable, wherein when an assistance braking specification is present: a faultfree implementation of the assistance braking specification which is requested in an automated fashion is detected if the actual dynamics variable deviates, taking into account a noise deviation, at least temporarily from the reference dynamics variable by a pulse deviation, and/or a faulty implementation of this assistance braking specification which is requested in an automated fashion is detected if the actual