Method for controlling a multiphase machine

What is claimed is: 1. A method for controlling a multiphase machine connected to a battery, the multiphase machine having a DC link provided with a DC link capacitor, phase windings, and a high side switch and a low side switch for each phase, the switches associated with the individual phases being acted on by control signals from a control unit, the method comprising: causing the control unit to provide the control signals for the switches associated with the individual phases in such a way that: sinusoidal phase currents are predefined, at least one phase current is connected at any point in time in each control cycle, a fixed, pulsed control pattern is present for each control cycle, control widths of actuating signals associated with the phases being constant in the pulsed control pattern, and control pulses associated with the individual phases are predefined in such a way that no time gaps between the control pulses occur and a DC link current which arises is minimized; and in order to set the minimum DC link current, varying at least one of positions of the control pulses within a control interval, an amplitude of a setpoint voltage, and a width of the individual control pulses by an offset of control durations. 2. The method as recited in claim 1 , wherein a control cycle corresponds to an angular range of 360°/(2·PZ), where PZ is the number of phases of the multiphase machine. 3. The method as recited in claim 1 , wherein a flattop method is used within a control cycle. 4. The method as recited in claim 1 , wherein a control frequency of the switches associated with the phases is tracked in such a way that an integer number of pulse patterns is provided in an angular range of 360°/(2·PZ). 5. A method for controlling a multiphase machine connected to a battery, the multiphase machine having a DC link provided with a DC link capacitor, phase windings, and a high side switch and a low side switch for each phase, the switches associated with the individual phases being acted on by control signals from a control unit, the method comprising: causing the control unit to provide the control signals for the switches associated with the individual phases in such a way that: sinusoidal phase currents are predefined, at least one phase current is connected at any point in time in each control cycle, a fixed, pulsed control pattern is present for each control cycle, control widths of actuating signals associated with the phases being constant in the pulsed control pattern, and control pulses associated with the individual phases are predefined in such a way that a DC link current which arises is minimized; and in order to set the minimum DC link current, varying at least one of positions of the control pulses within a control interval, an amplitude of a setpoint voltage, and a width of the individual control pulses by an offset of control durations; wherein the control widths of the actuating signals associated with the phases are ascertained based on the particular instantaneous voltage phasor. 6. A method for controlling a multiphase machine connected to a battery, the multiphase machine having a DC link provided with a DC link capacitor, phase windings, and a high side switch and a low side switch for each phase, the switches associated with the individual phases being acted on by control signals from a control unit, the method comprising: causing the control unit to provide the control signals for the switches associated with the individual phases in such a way that: sinusoidal phase currents are predefined, at least one phase current is connected at any point in time in each control cycle, a fixed, pulsed control pattern is present for each control cycle, control widths of actuating signals associated with the phases being constant in the pulsed control pattern, and control pulses associated with the individual phases are predefined in such a way that a DC link current which arises is minimized; and in order to set the minimum DC link current, varying at least one of positions of the control pulses within a control interval, an amplitude of a setpoint voltage, and a width of the individual control pulses by an offset of control durations; wherein a generator current is controlled via a gradation with the aid of one of the pulse patterns, an excitation current of the machine, a commutation angle, a pulsed battery current at a higher time level with buffering in the battery, and via a combination of at least two of the pulse patterns, the excitation current of the machine, the commutation angle, and the pulsed battery current at the higher time level with buffering in the battery.