Method for determining the drainage control of a hydraulic switching element of a transmission

The invention claimed is: 1. A method for determining a draining behavior of a hydraulically actuated shifting element ( 9 , 10 ) of a transmission ( 3 ), a first shifting element half of the shifting element being functionally connected to a transmission input shaft ( 6 ) that is couplable to a drive engine ( 2 ), and a second shifting element half of the shifting element being connectable to a drive output ( 4 ) of a vehicle drive-train ( 1 ) including the transmission, the method comprising: when a rotation speed of the transmission input shaft ( 6 ) is greater than a threshold value and the second shifting element half is decoupled from the drive output ( 4 ), shifting the shifting element ( 9 , 10 ) from a completely drained, open operating condition, by applying an actuating pressure (p 9 ), to a completely filled, closed operating condition and determining a reference filling time (tf) until the completely filled, closed operating condition of the shifting element ( 9 , 10 ) is reached; recognizing the completely filled, closed operating condition of the shifting element ( 9 , 10 ) when a rotational speed (n11) of the second shifting element half, that is connectable to the drive output ( 4 ), reaches a predefined threshold value (n11_schwell); when the completely filled, closed operating condition of the shifting element ( 9 , 10 ) is recognized, changing the shifting element ( 9 , 10 ) to the completely drained, open operating condition by adjusting the actuating pressure (p 9 ) for a predefined draining time to an appropriate level and, thereafter, changing the shifting element to the completely filled, closed operating condition; when the completely filled, closed operating condition is recognized, again adjusting the shifting element ( 9 , 10 ), in a direction toward the completely drained, open operating condition, by lowering the actuating pressure (p 9 ); and before the shifting element ( 9 , 10 ) reaches the completely drained, open operating condition, again changing the shifting element ( 9 , 10 ) to the completely filled, closed operating condition, and determining the filling time until the partially drained shifting element again reaches the completely filled, closed operating condition. 2. The method according to claim 1 , further comprising determining the reference filling time (tf) at least twice in succession. 3. The method according to claim 1 , further comprising, after a lapse of a predefined draining time, again changing the shifting element ( 9 , 10 ) to the completely filled, closed operating condition and, with reference to a ratio between the filling time and the reference filling time (tf), determining a filling extent of the shifting element ( 9 , 10 ) after the lapse of the predefined draining time. 4. The method according to claim 3 , further comprising iteratively carrying out the determination of the filling extent of the shifting element ( 9 , 10 ) until the draining time, that corresponds to a predefined filling extent of the shifting element ( 9 , 10 ), is determined. 5. The method according to claim 3 , further comprising iteratively carrying out the determination of the filling extent of the shifting element ( 9 , 10 ) until the draining time, required to reach the completely drained, open operating condition of the shifting element ( 9 , 10 ), is determined. 6. The method according to claim 3 , further comprising plotting a characteristic curve that depicts the draining behavior of the shifting element ( 9 , 10 ) by linear interpolation between the completely filled and closed operating condition in which the shifting element ( 9 , 10 ) is after a draining time equal to zero, the completely drained, open operating condition of the shifting element ( 9 , 10 ) in which the shifting element ( 9 , 10 ) is after the lapse of its draining time, and an intermediate value of the filling extent determined at a draining time that corresponds thereto. 7. The method according to claim 6 , further comprising adapting at least one of a rapid filling time and a pressure level of the actuating pressure (p 9 ) of the shifting element ( 9 , 10 ), during a rapid filling phase of the shifting element ( 9 , 10 ), by the characteristic curve to the filling extent of the shifting element ( 9 , 10 ) determined by way of the characteristic curve at a beginning of the rapid filling phase. 8. The method according to claim 7 , further comprising reducing at least one of the pressure level of the actuating pressure (p 9 ) and the rapid filling time as a function of the respective filling extent of the shifting element ( 9 , 10 ) determined at the beginning of the rapid filling phase. 9. The method according to claim 3 , further comprising utilizing a characteristic curve that depicts the draining behavior of the shifting element in a form of a polynomial of a second order which is determined as a function of the completely filled, closed operating condition in which the shifting element ( 9 , 10 ) is after a draining time equal to zero, the completely drained, open operating condition of the shifting element ( 9 , 10 ) in which the shifting element ( 9 , 10 ) is after the lapse of its draining time, and an intermediate value of the filling extent determined at a draining time that corresponds thereto. 10. The method according to claim 3 , further comprising adapting the filling extent which corresponds to at least one of a predefined draining time of the shifting element ( 9 , 10 ) and the draining time which corresponds to a predefined filling extent of the shifting element ( 9 , 10 ), as a function of at least one of a rotational speed of the transmission input shaft ( 6 ) and an operating temperature of the transmission ( 3 ).