Control device for a braking system of a vehicle, and method for operating a braking system of a vehicle

What is claimed is: 1. A control device for a braking system of a vehicle, comprising: an activating unit that sets a first setpoint brake pressure in at least one first wheel brake cylinder of a first brake circuit of the braking system, and that sets a second setpoint brake pressure in at least one second wheel brake cylinder of a second brake circuit of the braking system, wherein the activating unit sets the first setpoint brake pressure and the second setpoint brake pressure taking into consideration an input signal regarding a setpoint vehicle deceleration, the setpoint vehicle deceleration being predefined at least one of: i) by a driver using an actuation of a brake actuating element of the vehicle, and ii) by an automatic speed control of the vehicle, at least one component of the braking system being controlled with the aid of the activating unit so that a first actual brake pressure present in at least the first wheel brake cylinder of the first brake circuit is variable taking into account the established first setpoint brake pressure, and a second actual brake pressure present in the at least second wheel brake cylinder of the second brake circuit is variable taking the established second setpoint brake pressure into account; wherein at least one of: (a) the first actual brake pressure is reduced according to the established first setpoint brake pressure, and the second actual brake pressure is reduced according to the established second setpoint brake pressure, the activating unit being configured to output at least one first control signal to a master brake cylinder pressure varying device, which is controlled with the aid of the at least one first control signal in such a way that a master brake cylinder pressure is set in a master brake cylinder of the braking system to be no greater than a minimum of the first setpoint brake pressure and the second setpoint brake pressure, and output at least one second control signal to at least one of a first switchover valve of the first brake circuit and a second switchover valve of the second brake circuit, the first and second switchover valves being respectively controlled with the aid of the at least one second control signal in such a way that at least one of the first actual brake pressure and the second actual brake pressure is additionally reduced; and (b) the first actual brake pressure is increased according to the established first setpoint brake pressure, and the second actual brake pressure is increased according to the established second setpoint brake pressure, the activating unit being configured to output at least one third control signal to the master brake cylinder pressure varying device, which is controlled with the aid of the at least one third control signal in such a way that the master brake cylinder pressure is set to be no smaller than a maximum of the first setpoint brake pressure and the second setpoint brake pressure, and output at least one fourth control signal to at least one of a first wheel inlet valve of the first brake circuit and a second wheel inlet valve of the second brake circuit, the first and second wheel inlet valves being respectively controlled with the aid of the at least one fourth control signal in such a way that at least one of the first actual brake pressure and the second actual brake pressure is additionally increased. 2. The control device as recited in claim 1 , wherein the activating unit is configured to provide at least one of (i) a differential pressure control of the first actual brake pressure to be reduced through the first switchover valve with the aid of the at least one second control signal, and (ii) a differential pressure control of the second actual brake pressure to be reduced through the second switchover valve with the aid of the at least one second control signal. 3. The control device as recited in claim 1 , wherein the activating unit is configured to provide at least one of (i) a differential pressure control of the first actual brake pressure to be increased through the at least one first wheel inlet valve with the aid of the at least one fourth control signal, and (ii) a differential pressure control of the second actual brake pressure to be increased through the at least one second wheel inlet valve with the aid of the at least one fourth control signal. 4. The control device as recited in claim 1 , wherein the activating unit is configured to control at least one plunger as a master brake cylinder pressure varying device with the aid of at least one of the first control signal and the third control signal. 5. The control device as recited in claim 1 , wherein the activating unit is configured to establish at least one of the first setpoint brake pressure and the second setpoint brake pressure while additionally taking into account at least one generator braking torque exerted with the aid of at least one electric motor on at least one axle assigned to at least one of the first wheel brake cylinder and the second wheel brake cylinder. 6. The control device as recited in claim 1 , wherein the activating unit is configured to establish a setpoint variable regarding a booster force to be exerted on the brake actuating element with the aid of a brake booster, taking into account at least one of input signal, the first setpoint brake pressure, the second setpoint brake pressure, the ascertained first actual brake pressure, and the ascertained second actual brake pressure, and to output to the brake booster a brake booster control signal which corresponds to the setpoint variable. 7. The control device as recited in claim 1 , wherein the first switchover valve is situated between the master brake cylinder and at least one first wheel inlet valve assigned to the at least one first wheel brake cylinder, and the second switchover valve is situated between the master brake cylinder and at least one second wheel inlet valve assigned to the at least one second wheel brake cylinder valve. 8. A method for operating a braking system of a vehicle, comprising: establishing a first setpoint brake pressure to be set in at least one first wheel brake cylinder of a first brake circuit of the braking system and a second setpoint brake pressure to be set in at least one second wheel brake cylinder of a second brake circuit of the braking system, taking into account at least one setpoint variable regarding a setpoint vehicle deceleration to be exerted on the vehicle predefined at least one of (a) by a driver with the aid of an actuation of a brake actuating element of the vehicle and (b) by an automatic speed control of the vehicle; and varying a first actual brake pressure present in at least the first wheel brake cylinder of the first brake circuit, taking into account the established first setpoint brake pressure, and varying a second actual brake pressure present in at least the second wheel brake cylinder of the second brake circuit, taking into account the established second setpoint brake pressure, wherein the varying takes place by at least one of: (i) reducing the first actual brake pressure according to the established first setpoint brake pressure and reducing the second actual brake pressure according to the established second setpoint brake pressure by: setting a master brake cylinder pressure in a master brake cylinder of the braking system to be no greater than a minimum of the first setpoint brake pressure and the second setpoint brake pressure; and activating at least one of a first switchover valve of the first brake circuit for additionally reducing the first actual brake pressure and a second switchover valve of the second brake circuit for additionally reducing the second actual brake pressure; and (ii) increasing the first actual brake pr