EP2467930A1 - Electronically commutated electric motor featuring prediction of the rotor position and interpolation, and method - Google Patents

Abstract

The invention relates to an electronically commutated electric motor comprising a stator and an especially permanent-magnetic rotor. The electric motor also comprises a control unit which is effectively connected to the stator and is designed to generate control signals for commutating the stator in such a way that the stator can generate a rotating magnetic field in order to rotate the rotor. The electric motor further comprises at least one rotor position sensor which is designed to detect a position, especially an angular position, of the rotor and generate a rotor position signal representing the position of the rotor. The control unit is designed to generate the control signals in accordance with the rotor position signal. According to the invention, the control unit is designed to sample and quantize the rotor position signal and generate a digital rotor position signal. The digital rotor position signal forms a time-related data stream which corresponds to the sampled and quantized rotor position signal. The control unit includes an interpolator which is designed to generate at least one intermediate value in the digital rotor position signal, said intermediate value lying between two successive rotor position values.

Description

Electronically commutated electric motor with a rotor position prediction and an interpolation and

method

The invention relates to an electronically commutated

Electric motor. The electronically commutated electric motor has a stator and a particular permanent magnetic rotor formed. The electric motor also has a control unit which is operatively connected to the stator and configured to generate control signals for commutating the stator such that the stator can generate a magnetic rotating field for rotating the rotor. The electric motor also has at least one rotor position sensor which is designed to have a rotor position, in particular a rotor position

Angular position, the rotor to capture and a the

Rotor position signal representing rotor position to produce. The control unit is designed, the

To generate control signals in response to the rotor position signal.

From DE 103 32 381 Al an electric motor is known in which a rotor position of a rotor is detected sensorless and a current waveform of winding currents for rotating the rotor via a rotor rotation continuously without abrupt jumps and no power gaps for sensorless

Rotor position detection has. For fast rotating electronically commutated

 Electric motors is the problem that during a

Operation of the electric motor, the rotor position detection must be performed with a high detection frequency, if a frequent change of a Kommutierungsmusters should occur during a rotor revolution. The control unit of the electric motor then has to a correspondingly high Have computing capacity.

According to the invention, the control unit of the electronically commutated electric motor of the type mentioned above

configured to sample and quantize the rotor position signal and to generate a digital rotor position signal. The digital rotor position signal forms a temporal data stream corresponding to the sampled and

quantized rotor position signal corresponds, wherein the control unit comprises an interpolator, which

is formed, at least one lying between two temporally successive rotor position values

Intermediate value in the digital rotor position signal too

produce. By the interpolator, a sampling frequency of a particular analog rotor position signal

sampling and quantizing analog-to-digital converter advantageously be smaller than without the interpolator. This can be a computing power of the control unit, which

for example, is formed by an FPGA or an ASIC, advantageously smaller than without the interpolator. More preferably, the control unit is configured to generate the digital rotor position signal as a digital prediction rotor position signal, wherein the digital

Prediction rotor position signal, in particular the temporal data stream, at least one or a plurality of

future, via the rotor position signal in time

outgoing rotor position values. The interpolator is preferably designed to generate the intermediate value between two future rotor position values. By virtue of the prediction rotor position signal thus formed, the rotor position can advantageously be available for a current rotor position or for future rotor positions for commutating the electric motor. Further advantageously, the so predicted rotor position for commutating the electric motor are available before the rotor position sensor, in particular an angle sensor, after conversion of a

For example, analog rotor position signal in a

digital rotor position signal, so converted

 Rotor position signal for further signal processing can provide.

The rotor position sensor is preferably an angle sensor. The angle sensor is, for example, a giant magnetoresistive sensor (GMR sensor) or an anisotropic sensor.

Magneto-Resistive Sensor (AMR sensor). In another embodiment, the electric motor, for example, a plurality of Hall sensors, which are each designed to generate a particular analog rotor position signal. Preferably, the angle sensor, in particular the GMR sensor or AMR sensor is formed, a

to generate time-continuous, preferably continuous-time, an absolute rotor position representing, in particular analog rotor position signal. A

Angular resolution of the angle sensor is then through a

 Sampling rate of the analog rotor position signal analog-to-digital converting analog-to-digital converter determined.

In a preferred embodiment, the control unit is embodied, in particular the digital prediction rotor position signal as a function of further rotor positions detected by means of the rotor position sensor

in particular according to a principle to correct FIFO (FIFO = First-In-First-out). For this purpose, the prediction rotor position signal can be formed, for example, by a predetermined number of rotor position values, wherein the rotor position values are recorded with each new angle detected by the angle sensor, more preferably additionally by an analogue sensor. Converted digital converter - Rotor position value according to the principle FIFO be updated. This can advantageously be done with non-stationary motion patterns, the commutation of the electric motor. For example, the

Control unit act on the stator during a rotor rotation a variety of mutually different Kommutierungsmuster.

In a preferred embodiment, the control unit is designed to use the digital prediction rotor position signal by means of an approximation function as a function of

Rotor position signal to generate as an output function to be approximated. This can advantageously by means of

Rotor position sensor generated rotor position signal for future rotor positions can be estimated advantageous. Preferably, the approximation function is a polynomial, in particular at least second degree or exactly second or third degree. Further advantageous

 Embodiments of an approximation function are a spline function or an exponential function. The control unit has in an advantageous

 Embodiment, a timer, and is configured to generate the prediction rotor position signal in response to a time signal generated by the timer, wherein a clock frequency of the timer is greater than a repetition frequency of successive rotor position values of the digital

 Rotor position signal, and to commutate the stator in response to the prediction rotor position signal. Thereby, the stator can be advantageous depending on

Be commutated interpolation values of the prediction rotor position signal. The control unit may preferably be designed to change the commutation time to a preferably future one

Determine rotor position value of the prediction rotor position signal, and more preferably the stator on a

commute future rotor position value.

The invention also relates to a method for operating an electronically commutated electric motor, in particular of the electric motor described above. In the method, a rotor position is detected by means of a rotor position sensor and a rotor position corresponding to the rotor position

 Rotor position signal generated. Further, in the method, preferably the rotor position signal is sampled and

quantized, and a particular digital, a temporal data stream forming prediction rotor position signal

generated. The prediction rotor position signal represents the sampled and quantized rotor position signal and includes at least one or a plurality of future timers extending beyond the rotor position signal

Rotor position values. In a preferred embodiment of the method, the digital prediction rotor position signal is dependent on further, detected by means of the rotor position sensor

Rotor positions corrected.

In an advantageous embodiment variant of the method, the digital prediction rotor position signal is generated by forming an approximation function as a function of

Rotor position signal generated as an output function. The

The starting function is the function to be approximated, which can form support points for generating the approximation function. This allows the prediction

Rotor position signal also through one of the nodes be extrapolated - formed for example by means of the rotor position signal, or generated from this - area. The approximation function is preferably a polynomial function of the second or third degree. In a preferred embodiment of the method, a commutation of the stator takes place as a function of the prediction rotor position signal after a time interval has elapsed, the sequence corresponding to a predetermined commutation time. Preferably, the commutation takes place by means of

at least one, preferably predetermined,

 Commutation. This can cause the commutation

advantageously already before the presence of a rotor position value generated by means of the rotor position sensor

respectively. In the method, a determination of the future

 Rotor position value as a function of

 Approximation function, such as the polynomial, the

Spline function or another suitable one

 Approximation. The necessary multiplications can advantageously by a correspondingly fast

 Arithmetic unit done.

The control unit may be, for example, a microprocessor, a microcontroller or an FPGA (FPGA = Field Programmable Gate Array), or an ASIC (Application Specific Integrated Circuit). The control unit will

for example, controlled by a control program, which is stored on a disk and forms a computer program product together with the disk.

The invention also relates to a control unit according to the above-described type for an electric motor The control unit then has no rotor and no stator and is designed to be connected to a stator of an electric motor.

The invention will now be described below with reference to figures and further embodiments. Further

advantageous embodiments will become apparent from the features described above, as well as the features specified in the description of the figures, and the features specified in the dependent claims. Figure 1 shows an embodiment of an electronically koπtmutierten electric motor with the inventive

Control unit;

FIG. 2 shows a method for operating the electric motor shown in FIG. 1; Figure 3 shows a diagram which illustrates the operation of the electric motor shown in Figure 1 and the method shown in Figure 2.

FIG. 1 shows an exemplary embodiment of an electronically commutated electric motor 1. The electric motor 1 has a stator 10 with three stator coils, namely a stator coil 12, a stator coil 14 and a stator coil 16. The stator 10 also has an angle sensor which is a

for example, can generate analog rotor position signal. The angle sensor 18 is designed to detect a rotor position of a rotor 11 of the electric motor 1. The angle sensor

18 is connected by means of a connection 50 to a control unit 30 of the electric motor 1. The control unit 30 has an analog-to-digital converter 27, which on the input side with the connection 50 and thus with the angle sensor 18th

connected is. An angle resolution of the angle sensor is in Case of analogue, in particular time-continuous

formed rotor position signal determined by a sampling rate of the analog-to-digital converter. The analog-to-digital converter 27 is connected on the output side via a connecting line 54 to a polynomial generator 29.

The analog-to-digital converter 27 is configured to

received on the input side via the connection 50

To sample rotor position signal and to generate a temporal sequence of samples, each representing an amplitude value of the rotor position signal. The analog-to-digital converter 27 has an output side via a

Connecting line 54 connected to a polynomial generator 29. The polynomial generator 29 is formed, depending on the received via the connecting line 54, -

Rotor position of the rotor 11 - representing sampling values to produce an approximation function, which at least approximately represents a curve represented by the samples in places curve.

The polynomial generator is preferably formed, the

To produce approximation function by means of a least squares method.

The approximation function is preferably a polynomial,

in particular a second or third degree polynomial. It is also conceivable - in particular as a function of a required computing time of the polynomial generator - a polynomial more than third degree.

The polynomial generator 29 is designed to determine polynomial coefficients of the previously determined approximation function, in particular of the polynomial, and these are output on a coefficient line memory 32 via a connecting line 56 output. For this purpose, the polynomial generator 29 has, for example, an FIR filter for each polynomial coefficient, in this exemplary embodiment three exemplary FIR filters 36, 38 and 39. The coefficient memory 32 is designed to keep the polynomial coefficients generated by the polynomial generator 29 in stock. The coefficient memory 32 is connected on the output side via a connecting line 58 to a predictor 34. The predictor 34 is

formed in the coefficient memory 32

stored coefficients over the connecting line 58, and a temporally successive,

To generate rotor position values representing data stream and output this output side via the connecting line 60 to a control unit 42. The data stream comprises temporally successive future ones

 Rotor position values - shown dotted in this embodiment - which each have a future, of the

Angle sensor 18 not yet detected rotor position - especially with a higher angular resolution than the digital-generated by the analog-to-digital converter

 Rotor position signal - represent. The data stream in this embodiment forms the previously mentioned prediction rotor position signal.

The approximation function, in particular the polynomial, can be formed, for example, as follows: with y _β , _n (Δn) = predictor polynomial as approximation function; n = sample, integer or number <1; T _a = sampling period; g = degree of the polynomial; a = polynomial coefficient.

The control unit 42 is connected to a timer 40 and is designed to commutate the stator 10 at least in dependence on the prediction rotor position signal received via the connection line 60.

The control unit 42 is connected on the output side via a connection 53 to a power output stage 25 of the electric motor 1. The control unit 42 is formed, the

Power output stage 25 for generating a magnetic

Rotary field by means of the stator coils 12, 14 and 16

head for. The power output stage 25 is the output side via a connection 52 with the stator 10, and there connected to the stator coils 12, 14 and 16. The control unit 42 is designed to precisely determine the commutation times for commutating the stator 10 as a function of the particular high-resolution time signal received by the timer 40. The control unit 42 is connected on the input side via a bidirectional connection 61 to a memory 62. In the memory 62 to each other different Bestromungsmuster are kept in stock, one of which

Energizing pattern 62 is exemplified.

For example, the control unit 42, depending on the prediction rotor position signal to select a Bestromungsmuster the stock held in the memory and the stator 10 according to the Bestromungsmuster for generating the

Rotary field to energize.

The polynomial generator 29 may advantageously be available for each polynomial coefficient in the coefficient memory 32 held polynomial coefficients have a FIR (Finite Impulse Response) filter.

The control unit 42 is also on the input side via the

Connecting line 54 connected to the analog-to-digital converter 27 and can from the analog-to-digital converter

digitized rotor position signal received.

The control unit 42 is embodied, the power output stage 35 for commutating the stator coils in dependence on the rotor position values calculated by the predictor 34

to control accordingly. A time sequence frequency of the rotor position values of the predictor generated

Rotor position signal is greater than the repetition frequency of the digital-generated by the analog-to-digital converter

Rotor position signal. , FIG. 2 shows an exemplary embodiment of a method for commutating an electronically commutated electric motor. In the method, in a step 70, a rotor position of a rotor of the electronically commutated electric motor is detected, in particular by means of an angle sensor, and a rotor position signal is generated which comprises at least one

 Rotor position of the rotor represents. In a step 72, the rotor position signal is digitized by means of an analog-to-digital converter and a digitized

Rotor position signal generated. In a step 74, a polynomial is generated in dependence on the digitized rotor position signal, which digitizes the

At least approximately approximated rotor position values. In a step 76, polynomial coefficients

which represent the previously formed polynomial. In a step 78, by means of a

Predictors a polynomial depending on the previously generated Polynomial coefficients are formed and depending on the

Polynomial generates a data stream, which includes rotor position values in a time range in which the of the

Angle sensor detected rotor position values, and in addition to future rotor position values, which have not yet been detected by the angle sensor and / or are not yet represented by the signal generated by the analog-to-digital converter 24. Furthermore, in this exemplary embodiment, the data stream comprises rotor position values generated by interpolation, such that a time clock rate of the successive rotor position values of the data stream is greater than a sampling rate during analog-to-digital conversion. In a step 80, a commutation pattern is selected as a function of the data stream, and in a step 82 the stator is supplied with the commutation pattern.

FIG. 3 shows a diagram 90. The diagram 90 has a time axis 91 and an amplitude axis 92.

Diagram 90 shows a curve 95 which combines samples 101, 102, 104, 106, 108, 110, and 112 together. The curve 95 corresponds to a polynomial which has been generated, for example, by means of the polynomial generator 29 shown in FIG. 1, and which represents a rotor position profile. The polynomial 95 is in this

Embodiment a third degree polynomial. Rotor position values 101, 103, 105, 107, 109, 111 and 113 are also shown.

The rotor position value 101 has been detected by the angle sensor, for example by the angle sensor 18 shown in FIG. Shown are also a time interval 96 and a time interval 98. The time interval 96 represents a sampling period of an analog-to-digital converter, for example the analog-to-digital converter 27 shown in FIG. 1. The rotor position values 100, 102, 104, 106, 108 and 110 112 are respectively to preceding and following

Rotor position values by the time interval 96 spaced.

The rotor position value 101 follows the rotor position value 100 after the time interval 98. The rotor position value 103 follows the rotor position value 102 after the time interval 98. The time interval 98 represents one

Computing time that the analog-to-digital converter needs to digitize the sent from the angle sensor

Perform rotor position signals. The control unit - for example, the control unit 30 in

Figure 1 - is thus for further signal processing and to control the Kommutierungszeitpunkte that of the

Angle sensor detected rotor position signals in

digitized form later - delayed in this example by the time interval 98 - available when they have been detected by the angle sensor. Shown are the

Commutation times 115 and 117. The

 Commutation time 115 is spaced from rotor position value 102 by time interval 99. The time interval 99 is shorter than the time interval 98, so that the

 Commutation time 115 after the presence of the digital rotor position value 103 - which corresponds to the rotor position of the rotor position value 102 - takes place. Shown are also each representing a rotor position

Intermediate values 118, 119 and 120 generated by the interpolator. By generating the predictor polynomial and predicting future rotor position values derived from the

Angle sensor have not yet been detected, can advantageously be a sampling frequency for detecting a rotor position of the rotor lower than without the prediction by means of the predictor polynomial. Further advantageous is the low sampling frequency of the sampling of the rotor position signal by generating the intermediate values by means of interpolation

compensated or improved. For example, if rotor position values 100, 102, 104, and 106 have been detected by the angle sensor, rotor position value 108, rotor position value 110, and rotor position value 112, as well as intermediate values 118, 119, 120 may have been generated using the predictor polynomial. In a further course of the method for commutating the electric motor, the control unit, for example the control unit 42 in FIG. 1, compares the rotor position values 108, 110 and 112 generated by the predictor with those rotor position values 109, 111 and 113 detected by the angle sensor and for forming a further Polynomverlaufs of the predictor polynomial.

FIG. 4 shows an exemplary embodiment of a predictor 120 which, for example, can be a component of the electric motor 1 instead of the predictor 34 shown in FIG. The predictor 120 has an input 124 and an output 129. The input 124 is already with that in FIG

shown timer 40 connected. The input 124 is connected via a connecting line 121 to a multiplier 126 and a multiplier 128. The multiplier 126 is also connected to an adder 123 on the input side. The adder 123 has an input 131 with a connection 131 and connected via connection 131 to an input 132. The adder 123 may receive a polynomial coefficient via the input 132, in this embodiment a polynomial coefficient a _{2 of} a second degree polynomial. The multiplier 146 has its output connected to an adder 125. The adder 125 is the input side with the multiplier 126, and also the input side with the

multi-channel connection 131 connected. The adder 125 can receive a polynomial coefficient via the multi-channel connection 131 and thus from the input 132, in this embodiment a polynomial coefficient ai of the second-degree polynomial. The adder 125 is connected to the multiplier 128 on the output side. The multiplier 128 has its output connected to an adder 127. The adder 147 has an input side with the multiplier 128 and also with the input 132 via the input side

Connection 131 and can receive over the connection 131 a polynomial coefficient, in this embodiment, a polynomial coefficient a _{0 of} the second degree polynomial. The adder 127 has an output side with the

 Output 129 connected. The predictor 120, for example, when operating from the timer 41 via the input 124, may receive a particular ramped clock signal 43, the clock frequency of which is a multiple of a sampling frequency used by the analog-to-digital converter 27 during analog-to-digital conversion. The timing signal is formed, for example, ramped and has a predetermined number of ramp stages for each clock of the sampling period of the analog-to-digital conversion. With each time clock period received at the input 124, in particular

Ramp stage, the timing signal 43 multiplies the

Multiplier 126 is a received from the adder 123 Output signal with the timing signal and outputs on the output side a multiplication result to the adder 125. The adder 121 adds that from the multiplier 126

received multiplication result with the polynomial coefficients ai and ai received from the input 132

On the output side, a corresponding addition result to the multiplier 128. The multiplier 128 multiplies the addition result received from the adder 125 by the clock signal which is also supplied to the multiplier 126 by the multiplier 126

Input 124 has received. The multiplier 128 generates a corresponding multiplication result and outputs this to an adder 127 on the output side. The adder 127 adds the one generated by the multiplier 128

Multiplication result with a polynomial coefficient ao, the adder 127 has received from the input 132 via the connection 131. The adder 127 can then do the

Output result to the output 129 - as a prediction rotor position signal - output. The adder 123 can input side - shown dotted - in the case of

Polynomial more than second degree with at least one

be connected to other multipliers. The input 132 is, for example, with the one shown in FIG

Connecting line 58 and so connected to the coefficient memory 32. FIG. 5 shows an exemplary embodiment of a predictor 130. The predictor 130 can replace the predictor 34 in FIG. 1, for example. In contrast to the predictor 120 in FIG. 4, the predictor 130 has no multipliers and can therefore be provided in a cost-effective manner, for example by means of an ASIC.

The predictor 130 has an input 135 and an output 165 and is connected to a timer 134. The predictor 130 has a plurality of integrators, in particular together forming a cascade. The integrators each have an adder and a memory.

Shown is an adder 132, which is connected on the output side via a connecting line 152 to a memory 133. The memory 133 is on the output side via a

Connection line 154 is connected to a further adder 136. The memory 133 is also connected on the output side via a feedback connection line 150 to the adder 132. The adder 132 forms an integrator together with the memory 133.

The memory 133 is on the output side via a

Connection line 154 is connected to the adder 136. The adder 136 is connected on the output side via a connecting line 156 to a memory 137. The memory 137 is connected on the output side via a connecting line 158 to the adder 136 in a feedback manner. The memory 147 is

On the output side also connected via a connecting line 160 to an adder 138. The adder 138 is

on the output side via a connecting line 162 with the

Output 165 connected.

The adder 138, the adder 136 and the adder 132 are each connected on the input side to an input 135 and can via the input 135 polynomial coefficients

receive. The predictor 130 may be connected via the input 135 to, for example, the one shown in FIG

Coefficient memory 32 and be connected by the

Coefficient memory 32 which receives polynomial coefficients.

The polynomial coefficients can be generated by the polynomial generator 29, for example, as follows, in particular as a function of the sampling rate of the analog-to-digital converter 27 in FIG become: t> o = a _o with bo, bι, b2, clock-dependent polynomial coefficients L = a multiple of the sampling frequency T _{a of} the analog-to-digital converter 27 in Figure 1

The arithmetic unit formed by the predictor 130 may, for example, by a microprocessor, a

Microcontroller or an FPGA (Field Programmable Gate Array FPGA), or an ASIC (Application Specific Integrated Circuit) be realized. The connection

between the input 134 and the adder 132 is shown partially dotted. That is, the predictor 130 may include, for example, other integrators connected to the adder 132 for computing a higher order polynomial. The predictor 130 is also connected to a timer 134 on the input side. By way of example, the timer 134 is designed to generate a time signal which has an in particular L-fold higher clock rate than a sampling rate used by the analog-to-digital converter 27.

The integrators of the predictor 130 are each connected to the timer 134 and each carry one

Arithmetic operation with the predetermined by the timer 134 timing. The polynomial coefficients bo, bi and b ₂ are provided by the input 135 at the sampling frequency clock. The timer 134 is for example designed to generate the clock for clocking the integrators according to the following rule:

JTakt -L-- a with fTakt = clock frequency of the clock for clocking the clock

 integrators,

T _a = sampling period, for example of the analog-to-digital converter 27 in FIG. 1

L = factor, advantageously as power L = 2 ⁿ Advantageously, the factor L is chosen as a power to a base 2. The division operations for generating the polynomial coefficients bo, bi and b2, more preferably b _n , can thus be advantageously produced by means of addition operations. The predictor 130 can thus at the output 165 by means of the am

Input 135 received polynomial coefficients generated

 Polynomial output - as a prediction rotor position signal. The output 165 may, for example, be connected to the connecting line 60 shown in FIG. 1, so that the predictor 130 is connected on the output side to the control unit 42. The control unit 42 may, for example, in

Dependency of the polynomial received from the predictor 130 ^■ as a prediction rotor position signal - from the memory 65 select a Bestromungsmuster 62, and energize the stator 10 of the electric motor 1 by means of the power amplifier 25 according to the Bestromungsmuster.

Claims

claims

1. Electronically commutated electric motor (1), with a stator (10) and in particular

permanent magnetically formed rotor (11), and a

Control unit (30), which is operatively connected to the stator and formed to generate control signals for commutating the stator (10, 12, 14, 16) such that the stator (10, 12, 14, 16) a magnetic rotating field for rotating the Rotor (11) and the electric motor (1) has at least one rotor position sensor (18) which is designed to detect a rotor position of the rotor (11) and to generate a rotor position signal representative of the rotor position, and the control unit (30) is formed is to generate the control signals in response to the rotor position signal, characterized in that the control unit (30) is formed, the

 To sample and quantify the rotor position signal {21), and a digital rotor position signal (95, 100, 102, 104, 106, 108, 110, 112} to produce a temporal

 Data stream which corresponds to the sampled and quantized rotor position signal, the control unit having an interpolator which is designed

to generate at least one intermediate value (118, 119, 120} lying between two temporally successive rotor position values in the digital rotor position signal.

2. Electric motor (1) according to claim 1, characterized in that the control unit is designed, the digital Rotor position signal to generate as a digital prediction rotor position signal, which at least one or a plurality of future, on the

Rotor position signal time out

Rotor position values (108, 110, 112) comprises and the

 Interpolator (34) is adapted to generate the intermediate value (118, 119, 120) between two future rotor position values (108, 110, 112).

3. Electric motor (1) according to claim 2, characterized in that the control unit (30)

is formed, the digital prediction rotor position signal (95, 100, 102, 104, 106, 108, 110, 112) in dependence on further, by means of the rotor position sensor (18) detected

Correct rotor positions.

4. Electric motor (1) according to claim 2 or 3, characterized in that the control unit (30)

is designed to handle the digital prediction

Rotor position signal (95, 100, 102, 104, 106, 108, 110, 112) by means of an approximation function in response to the rotor position signal (100, 102, 104, 106) as

To generate output function.

5. Electric motor (1) according to claim 4, characterized in that the approximation function is a polynomial in particular

at least second degree.

6. Electric motor {1} according to one of the preceding claims, characterized in that the control unit (30) comprises a timer (134) and is arranged to generate the prediction rotor position signal (95) in dependence on a time signal generated by the timer (134), wherein a

 Clock frequency of the timer is greater than a repetition frequency of successive rotor position values of the digital

Rotor position signal, and the stator in response to the prediction rotor position signal (95) to commutate (115, 117).

7. A method for operating an electronically commutated electric motor with a rotor, in particular according to one of claims 1 to 5, wherein by means of a

Rotor position sensor (18) a rotor position of a rotor (11) is detected and a rotor position signal corresponding to the rotor position is generated, and wherein the

Rotor position signal is sampled and quantized, and a digital, a temporal data stream forming

Rotor position signal (95, 100, 102, 104, 106, 108, 110, 112) is generated, which the sampled and quantized

Rotor position signal represents, by means of

Interpolation at least one between two times

successive rotor position values

Intermediate value (118, 119, 120) in the digital

Rotor position signal is generated.

8. The method of claim 7, wherein the digital rotor position signal as a digital

Prediction rotor position signal (95, 100, 102, 104, 106, 108, 110, 112) is generated, which at least one or a plurality of future, via the rotor position signal includes rotor position values (108, 110, 112) that extend beyond time and that the interpolator is designed, the

Intermediate value between two future rotor position values.

9. The method of claim 8, wherein the digital

 Prediction rotor position signal (95, 100, 102, 104, 106, 108, 110, 112) is corrected in response to other, detected by the rotor position sensor rotor positions according to a first-in-first-out principle.

10. The method according to claim 8 to 9, characterized in that the digital prediction rotor position signal by forming an approximation function in dependence of

Rotor position signal is generated as an output function.

11. The method according to claim 10, characterized in that the Äpproximationsfunktion is a polynomial function, in particular at least second degree.

12. The method according to any one of claims 9 or 10, characterized in that the Äpproximationsfunktion is a inepline function.

13. The method according to any one of claims 8 to 12, characterized in that in dependence of the prediction rotor position signal (95, 100, 102, 104, 106, 108, 110, 112) a commutation (115, 117) of the stator, preferably by means of a commutation pattern.