Method and device for monitoring an engagement process of an engaging pinion of a starter motor

What is claimed is: 1. A method for monitoring an engagement process of an engaging pinion of a starter motor for a vehicle drive, in which an armature of the starter motor is moved by a solenoid having a magnet having a magnetic coil, the method comprising: starting the engagement process by setting the armature of the starter motor in motion via the solenoid, wherein the magnetic coil of the solenoid is supplied with current; detecting a magnetic coil signal of the magnetic coil when current is applied to the magnetic coil of the magnet, to obtain a signal profile; generating a frequency profile by transforming the signal profile using a time-frequency transform; comparing the frequency profile to at least two reference frequency profiles, wherein one of the reference frequency profiles is associated with a successfully carried out engagement process, and another of the reference frequency profiles is associated with an unsuccessfully carried out engagement process; and monitoring the engagement process based on the comparison by ascertaining a quality of the engagement process. 2. The method as recited in claim 1 , wherein it is ascertained during the monitoring of the engagement process whether the engagement process is able to be carried out successfully. 3. The method as recited in claim 1 , wherein, in response to the generating of the frequency profile, at least one of the following transforms is used: a discrete Fourier transform, a fast Fourier transform (FFT), a short-time Fourier transform (STFT), and a wavelet transform. 4. The method as recited in claim 1 , wherein the comparing includes ascertaining an error value based on a mean square error between the frequency profile and the at least one reference frequency profile. 5. The method as recited in claim 1 , wherein the comparing includes correlating the frequency profile with the at least one reference frequency profile. 6. The method as recited in claim 1 , wherein the comparing takes place to a first number of reference frequency profiles, which are each associated with a successfully carried out engagement process, and a second number of reference frequency profiles, which are each associated with an unsuccessfully carried out engagement process. 7. The method as recited in claim 1 , wherein the monitoring of the engagement process includes ascertaining a particular reference frequency profile from which the frequency profile has a smallest deviation. 8. The method as recited in claim 1 , wherein the signal profile is submitted to a scanning rate conversion before the generating of the frequency profile. 9. The method as recited in claim 1 , wherein the signal profile is brought to a specified number of scanning values before the generating of the frequency profile. 10. The method as recited in claim 1 , wherein the generating of the frequency profile is replaced by observing of the signal profile, so as to obtain an observation profile; and wherein the frequency profile is replaced by the observation profile, and the comparing of the frequency profile to at least one reference frequency profile is replaced by a comparison of the observation profile to at least one reference frequency profile. 11. The method as recited in claim 10 , wherein the observation profile is obtained by a Kalman filtering of the signal profile or by using a real-time model of mechanical kinematics and/or electrical parameters. 12. A device for monitoring an engagement process of an engaging pinion of a starter motor for a vehicle drive, wherein an armature of the starter motor is moved by a solenoid having a magnet having a magnetic coil, comprising: a sensor configured to detect a magnetic coil signal when a current acts on a magnetic coil of the magnet, so as to obtain a signal profile, wherein the engagement process is started by setting the armature of the starter motor in motion via the solenoid, wherein the magnetic coil of the solenoid is supplied with current; and a processor configured to perform the following: detecting a magnetic coil signal of the magnetic coil when current is applied to the magnetic coil of the magnet, to obtain a signal profile; generating a frequency profile by transforming the signal profile using a time-frequency transform; comparing the frequency profile to at least two reference frequency profiles, wherein one of the reference frequency profiles is associated with a successfully carried out engagement process, and another of the reference frequency profiles is associated with an unsuccessfully carried out engagement process; and monitoring the engagement process based on the comparison by ascertaining a quality of the engagement process. 13. A device for monitoring an engagement process of an engaging pinion of a starter motor for a vehicle drive, wherein an armature of the starter motor is moved by a solenoid having a magnet having a magnetic coil, comprising: a sensor configured to detect a magnetic coil signal when a current acts on a magnetic coil of the magnet, so as to obtain a signal profile, wherein the engagement process is started by setting the armature of the starter motor in motion via the solenoid, wherein the magnetic coil of the solenoid is supplied with current; and a processor configured to perform the following: detecting a magnetic coil signal of the magnetic coil when current is applied to the magnetic coil of the magnet, to obtain a signal profile; generating an observation profile by observing the signal profile; comparing the observation profile to at least two reference frequency profiles, wherein one of the reference frequency profiles is associated with a successfully carried out engagement process, and another of the reference frequency profiles is associated with an unsuccessfully carried out engagement process; and monitoring the engagement process based on the comparison by ascertaining a quality of the engagement process. 14. The device as recited in claim 13 , wherein the observation profile is obtained by a Kalman filtering of the signal profile or by using a real-time model of mechanical kinematics and/or electrical parameters.