Simulation of a field-oriented stator voltage of a stator of an asynchronous machine steadily required during operation

The invention claimed is: 1. A method for operating an asynchronous machine, without a rotary encoder, the method comprising: determining, with a transformation device, (i) a detected field-oriented stator voltage based on a detected stator-oriented stator voltage received from a first sensor and (ii) a detected field-oriented stator current based on a detected stator-oriented stator current received from a second sensor; estimating, with a control unit configured to receive the detected field-oriented stator voltage and the detected field-oriented stator current, a required field-oriented stator voltage for steady state operation based on the detected field-oriented stator voltage, the detected field-oriented stator current, and a model, the estimating of the required field-oriented stator voltage at least comprising: integrating, with a first proportional integrator of the control unit, the detected field-oriented stator voltage over a first time with a normalization constant that is indicative of a stator inductance of the stator; and subtracting, with a first combination element of the control unit, the detected field-oriented stator current from the integrated field-oriented stator voltage in order to generate a field-oriented differential current; and controlling, with a current control unit configured to receive the estimated required field-oriented stator voltage and a setpoint for the field-oriented stator current, a field-oriented stator current of the asynchronous machine by applying graduated voltages to the asynchronous machine based on the estimated required field-oriented stator voltage and the setpoint for the field-oriented stator current. 2. The method as claimed in claim 1 , the estimating of the required field-oriented stator voltage further comprising: amplifying, with an amplifier of the control unit, the field-oriented differential current with an adjustable gain parameter; and subtracting, with a second combination element of the control unit, the amplified field-oriented differential current from the field-oriented detected stator voltage prior to the integrating of the detected field-oriented stator voltage. 3. The method as claimed in claim 1 , the estimating of the required field-oriented stator voltage further comprising: integrating, with a second proportional integrator of the control unit, the field-oriented differential current over a second time with an adjustable further normalization constant to generate the required field-oriented stator voltage; and subtracting, with a second combination element of the control unit, the required field-oriented stator voltage from the detected field-oriented stator voltage prior to the integrating of the field-oriented detected stator voltage. 4. The method as claimed in claim 1 , wherein a first time scale on which the required field-oriented stator voltage is simulated is smaller than a second time scale on which the field-oriented stator current is controlled. 5. The method as claimed in claim 1 , wherein the model is a machine model. 6. An apparatus for operating an asynchronous machine without a rotary encoder, the apparatus comprising: a transformation device configured to determine (i) a detected field-oriented stator voltage based on a detected stator-oriented stator voltage received from a first sensor and (ii) a detected field-oriented stator current based on a detected stator-oriented stator current received from a second sensor; a control unit configured to receive the detected field-oriented stator voltage and the detected field-oriented stator current, the control unit configured to estimate a required field-oriented stator voltage for steady state operation based on the detected field-oriented stator voltage, the detected field-oriented stator current, and a model, the control unit at least comprising: a first proportional integrator configured to integrate the detected field-oriented stator voltage over a first time with a normalization constant that is indicative of a stator inductance of the stator; and a first combination element configured to subtract the detected field-oriented stator current from the integrated field-oriented stator voltage in order to generate a field-oriented differential current; and a current control unit configured to receive the estimated required field-oriented stator voltage and a setpoint for the field-oriented stator current and control a field-oriented stator current of the asynchronous machine by applying graduated voltages to the asynchronous machine based on the estimated required field-oriented stator voltage and the setpoint for the field-oriented stator current. 7. The simulation apparatus as claimed in claim 6 , wherein the model is a machine model. 8. The simulation apparatus as claimed in claim 6 , the control unit further comprising: an amplifier configured to amplify the field-oriented differential current with an adjustable gain parameter; and a second combination element configured to subtract the amplified field-oriented differential current from the field-oriented detected stator voltage prior to the integrating of the detected field-oriented stator voltage. 9. The simulation apparatus as claimed in claim 6 , the control unit further comprising: a second proportional integrator configured to integrate the field-oriented differential current over a second time with an adjustable further normalization constant to generate the required field-oriented stator voltage; and a second combination element configured to subtract the required field-oriented stator voltage from the detected field-oriented stator voltage prior to the integrating of the field-oriented detected stator voltage.