Method for protecting a controllable semiconductor switch from overload and short-circuiting in a load circuit

The invention claimed is: 1. A method for the protection of a controllable semiconductor switch against overload and short-circuiting in a load circuit, wherein the method comprises: detecting an input voltage of the semiconductor switch; detecting an output voltage of the semiconductor switch; computing, by a comparator, a difference between the detected output voltage and the detected input voltage; comparing, by a comparison circuit including an AND logic gate, the difference to a predicted switching progress computed by a controller that indicates a predicted output voltage at a specified time based on a predetermined characteristic curve of the semiconductor switch; triggering, by the controller, a control signal to activate the semiconductor switch in response to the AND logic gate indicating that the difference accords with the predicted switching progress; and triggering, by the controller, the control signal to deactivate the semiconductor switch in response to the AND logic gate indicating that the difference does not accord with the predicted switching progress. 2. The method as claimed in claim 1 , wherein the detecting the output voltage of the semiconductor switch and comparing the detected output voltage with the predicted switching progress are carried out at least once before the semiconductor switch is fully switched on. 3. The method as claimed in claim 2 , wherein the detecting an output voltage and comparing the detected output voltage with the predicted switching progress are repeated at least once. 4. The method as claimed in claim 1 , wherein the detecting the output voltage and comparing the detected output voltage with the predicted switching progress are repeated at least once. 5. The method as claimed in claim 4 , wherein the detecting the output voltage and comparing the detected output voltage with the predicted switching progress are repeated at cascaded moments in time. 6. The method as claimed in claim 1 , wherein the predicted switching progress is freely programmable. 7. The method as claimed in claim 1 , wherein the method further comprises: measuring a current in the load circuit and/or a voltage drop at the semiconductor switch, as soon as the semiconductor switch is fully switched on; comparing the measured current and/or the measured voltage drop with a specified limit value; and deactivating the semiconductor switch if the measured current and/or the measured voltage drop is larger than the specified limit value. 8. A protective circuit for a controllable semiconductor switch against overload and short-circuiting in a load circuit, the protective circuit comprising: a monitoring circuit for detecting an input voltage of the semiconductor switch and detecting an output voltage of the semiconductor switch; at least one comparator for computing a difference between the detected output voltage and the detected input voltage; and a controller for: comparing, by a comparison circuit including an AND logic gate, the difference to a predicted switching progress that indicates a predicted output voltage at a specified time based on a predetermined characteristic curve of the semiconductor switch, triggering a control signal to activate the semiconductor switch in response to the AND logic gate indicating that the difference accords with the predicted switching progress, and triggering the control signal to deactivate the semiconductor switch in response to the AND logic gate indicating that the difference does not accord with the predicted switching progress. 9. The protective circuit as claimed in claim 8 , further comprising, evaluation logic receiving input from the controller. 10. The protective circuit as claimed in claim 9 , wherein the controller is a microcontroller with a data interface for programming the predicted switching progress. 11. The protective circuit as claimed in claim 8 , wherein the controller is a microcontroller with a data interface for programming the predicted switching progress. 12. The protective circuit as claimed in claim 8 , wherein the semiconductor switch is a power MOSFET.