Sensor device including a sensor for carrying out surrounding-area monitoring with the aid of sonic waves

What is claimed is: 1. A sensor device, comprising: a sensor; a signal generator; a monitoring unit; and a first control unit; wherein a sound transducer of the sensor is configured to emit sonic waves as a result of excitation of the sound transducer by electrical excitation signals produced with the signal generator, and to convert received sonic waves to electrical signals; wherein an evaluation unit of the sensor is configured to carry out surrounding-area monitoring during a normal operation of the sensor, by evaluating electrical signals of the sound transducer; wherein during a monitoring mode of the sensor, the monitoring unit is configured to measure an impedance of the sound transducer for different excitation frequencies of the excitation signals; wherein a first signal path and a second signal path are each connected to the sound transducer, and each are connectable to the signal generator, the first signal path including an amplifier, and the second signal path including an impedance output stage and a resistor; wherein the first control unit is configured to disconnect the first signal path from the signal generator and to connect the second signal path to the signal generator, so as to reset the sensor from the normal operation to the monitoring mode and in such a manner that the sound transducer receives the excitation signals via the second signal path and not via the first signal path, and the first control unit is configured to disconnect the second signal path from the signal generator and to connect the first signal path to the signal generator so as to reset the sensor from the monitoring mode to the normal operation and in such a manner that the sound transducer receives the excitation signals via the first signal path and not via the second signal path. 2. The sensor device of claim 1 , wherein the first signal path and the second signal path constitute two signal paths completely different from each other. 3. The sensor device of claim 1 , further comprising: a switch element, which has a first switching state and a second switching state, configured to be settable to the first switching state and second switching state with the first control unit, and configured to connect the first signal path to the signal generator in the first switching state and to connect the second signal path to the signal generator in the second switching state. 4. The sensor device of claim 1 , wherein an input of the impedance output stage is connectable to the signal generator, and wherein an output of the impedance output stage is connected to the sound transducer via the resistor. 5. The sensor device of claim 1 , further comprising: a second control unit, which is configured to control the signal generator so that during the monitoring mode, the excitation signals produced with the signal generator each have a lower amplitude, the lower amplitude at least one power of ten lower than during normal operation. 6. The sensor device of claim 1 , wherein the resistor of the second signal path is manufactured to be highly resistive, which is a resistance value of at least 1×10 5 Ω. 7. A method for monitoring a functional state of a sensor of a sensor device, the method comprising: resetting the sensor from the normal operation to the monitoring mode, by disconnecting the first signal path from the signal generator and connecting the second signal path to the signal generator in such a manner that the sound transducer receives the excitation signals via the second signal path; and measuring the impedance of the sound transducer for different excitation frequencies of the excitation signals produced with the signal generator; wherein the sensor device includes: a sensor; a signal generator; a monitoring unit; and a first control unit; wherein a sound transducer of the sensor is configured to emit sonic waves as a result of excitation of the sound transducer by electrical excitation signals produced with the signal generator, and to convert received sonic waves to electrical signals; wherein an evaluation unit of the sensor is configured to carry out surrounding-area monitoring during a normal operation of the sensor, by evaluating electrical signals of the sound transducer; wherein during a monitoring mode of the sensor, the monitoring unit is configured to measure an impedance of the sound transducer for different excitation frequencies of the excitation signals; wherein a first signal path and a second signal path are each connected to the sound transducer and each are connectable to the signal generator, the first signal path including an amplifier, and the second signal path including an impedance output stage and a resistor; wherein the first control unit is configured to disconnect the first signal path from the signal generator and to connect the second signal path to the signal generator, so as to reset the sensor from normal operation to a monitoring mode and in such a manner that the sound transducer receives the excitation signal via the second signal path and not via the first signal path, and the first control unit is configured to disconnect the second signal path from the signal generator and to connect the first signal path to the signal generator, so as to reset the sensor from the monitoring mode to the normal operation and in such a manner that the sound transducer receives the excitation signals via the first signal path and not via the second signal path. 8. The method of claim 7 , further comprising: controlling the signal generator so that during the monitoring mode, the excitation signals produced with the signal generator each have a lower amplitude than during normal operation. 9. The method of claim 7 , further comprising: controlling the signal generator so that during the monitoring mode, the excitation signals produced with the signal generator each have a lower amplitude, which is an amplitude at least one power of ten lower, than during normal operation.