A timepiece movement includes a stepping motor having a rotor for rotating an indicating hand, and a control unit for rotating the rotor by using a main drive pulse and an auxiliary drive pulse. When the indicating hand is rotated using a detection drive pulse based on the main drive pulse, the control unit determines a reference position of the indicating hand by detecting a rotation state of the rotor.

In accordance with at least one example of the description, a circuit is adapted to be coupled to a coil of a motor via an H-bridge circuit. The circuit includes a duty sensor, a subtractor, and a comparator. The duty sensor is coupled to the coil of the motor and is configured to provide raw run duty data responsive to a coil current through the coil. The subtractor is coupled to the duty sensor and is configured to provide a differential duty signal responsive to a stall duty signal and a run duty signal obtained using the raw run duty data. The comparator is coupled to the subtractor and is configured to provide a stall signal indicative of a stall condition for the motor responsive to the differential duty signal and a threshold value.

A timepiece includes a determination unit configured to execute determination processing of determining whether a braking force that brakes a rotor is preferably large or small, the rotor being rotated in a normal rotation direction to rotate a pointer clockwise; and a detection control unit configured to cause execution of rotation detection processing of detecting rotation of the rotor based on a first induced voltage output to a predetermined terminal among the first terminal and the second terminal being connected to a coil configured to generate a magnetic flux to rotate the rotor in the normal rotation direction, the predetermined terminal being selected based on the determination by the determination unit.

A timepiece includes a determination unit configured to execute determination processing of determining whether a braking force that brakes a rotor is preferably large or small, the rotor being rotated in a normal rotation direction to rotate a pointer clockwise; and a detection control unit configured to cause execution of rotation detection processing of detecting rotation of the rotor based on a first induced voltage output to a predetermined terminal among the first terminal and the second terminal being connected to a coil configured to generate a magnetic flux to rotate the rotor in the normal rotation direction, the predetermined terminal being selected based on the determination by the determination unit.

The disclosure relates to a drug delivery device having a drive unit includes a stator comprising a plurality of coils consecutively arranged in an axial direction, and an armature axially movable within the stator, the armature including a number of magnets and pole shoes consecutively arranged in the axial direction. A respective pole shoe is arranged between respectively neighbouring magnets. At least one axial end of the armature comprises a terminal pole shoe.

The disclosure relates to a drug delivery device having a drive unit includes a stator comprising a plurality of coils consecutively arranged in an axial direction, and an armature axially movable within the stator, the armature including a number of magnets and pole shoes consecutively arranged in the axial direction. A respective pole shoe is arranged between respectively neighbouring magnets. At least one axial end of the armature comprises a terminal pole shoe.

A method and a circuit assembly are described with which, in a stepper motor, a mechanical load applied to the motor shaft of which can be detected without a sensor in a voltage-based operating mode in which a nominal coil current is generated by applying a predetermined coil voltage (Us) to the coil. The coil is connected in a bridge branch of a bridge circuit formed from a first to fourth semiconductor switch (S1, . . . S4), wherein the predetermined coil voltage (Us) is applied to the coil with a variable duty cycle (T) by switching the semiconductor switch in the form of at least one PWM voltage (U(A1), U(A2)). The motor load is detected in the form of a load indicator signal (L) which represents a phase shift between a zero crossing of the predefined coil voltage (Us) and the next zero crossing of the coil current (Icoil) generated thereby, wherein a zero crossing of the coil current (Icoil) is defined when, in those time intervals (tm) in which the PWM voltage (U(A1), U(A2)) applied to the coil is zero, a polarity change occurs in a voltage dropping across the internal resistances of the semiconductor switches due to the coil current.

A method and a circuit assembly are described with which, in a stepper motor, a mechanical load applied to the motor shaft of which can be detected without a sensor in a voltage-based operating mode in which a nominal coil current is generated by applying a predetermined coil voltage (Us) to the coil. The coil is connected in a bridge branch of a bridge circuit formed from a first to fourth semiconductor switch (S1, . . . S4), wherein the predetermined coil voltage (Us) is applied to the coil with a variable duty cycle (T) by switching the semiconductor switch in the form of at least one PWM voltage (U(A1), U(A2)). The motor load is detected in the form of a load indicator signal (L) which represents a phase shift between a zero crossing of the predefined coil voltage (Us) and the next zero crossing of the coil current (Icoil) generated thereby, wherein a zero crossing of the coil current (Icoil) is defined when, in those time intervals (tm) in which the PWM voltage (U(A1), U(A2)) applied to the coil is zero, a polarity change occurs in a voltage dropping across the internal resistances of the semiconductor switches due to the coil current.

An electrical rotating machine includes a machine housing accommodating a rotor, and a stator. In order to allow the method to be carried out without structural changes to the electrical rotating machine a first physical value of the stator and a second physical value of the rotor are measured outside the machine housing, and a state variable of the electrical rotating machine is determined from the first physical value and the second physical value. The state variable, or alternatively the first and second physical value, are sent to a cloud, in particular wirelessly or by hardwired or optical means.

An electrical rotating machine includes a machine housing accommodating a rotor, and a stator. In order to allow the method to be carried out without structural changes to the electrical rotating machine a first physical value of the stator and a second physical value of the rotor are measured outside the machine housing, and a state variable of the electrical rotating machine is determined from the first physical value and the second physical value. The state variable, or alternatively the first and second physical value, are sent to a cloud, in particular wirelessly or by hardwired or optical means.