Double saliency exterior rotor switched reluctance machine with increasing and decreasing flux linkages and permanent magnets

The invention claimed is: 1. A switched reluctance machine comprising: a stator further comprising a back iron and a set of stator poles connected to the back iron; a rotor, adjacent the stator, rotatively coupled to the stator and connected to a shaft; the rotor further comprising a set of rotor segments; a housing connected to the stator and adjacent the rotor; a set of stator windings alternately disposed between the set of stator poles; a set of phases, each phase comprising a subset of the set of stator windings; whereby selectively energizing the set of phases with a set of current pulses rotates the rotor with respect to the stator and the housing; a first rotor segment of the rotor segments including a first permanent magnet with a polarity that is substantially tangential to a direction of motion the rotor; a circuit configured to provide: a first current pulse of the set of current pulses of a first phase of the set of phases; a second current pulse of the set of current pulses of the first phase of the set of phases; a third current pulse of the set of current pulses of the first phase of the set of phases; a fourth current pulse of the set of current pulses of the first phase of the set of phases; the first current pulse followed by the second current pulse followed by the third current pulse followed by a fourth current pulse; the first current pulse and the fourth current pulse each having a same polarity; and, the second current pulse and the third current pulse having a same polarity that is opposite the polarity of the first current pulse and the third current pulse. 2. The switched reluctance machine of claim 1 , wherein the circuit is further configured to provide: the second current pulse ending about 40 degrees of rotor rotation after a start of the first current pulse; the third current pulse starting about 20 degrees of rotor rotation after an ending of the second current pulse; the fourth current pulse ending about 40 degrees of rotor rotation after a start of the third current pulse; and, the first current pulse, the second current pulse, the third current pulse, and the fourth current pulse to each last about 15 degrees of rotor rotation. 3. The switched reluctance machine of claim 2 , wherein the circuit is further configured to provide: a fifth current pulse of the set of current pulses of the first phase of the set of phases that has a same polarity as the first current pulse and the fourth current pulse and follows the fourth current pulse; a start of the fifth current pulse separated from a start of the first current pulse by a rotor rotation of about 120 degrees; and, a start of the fifth current pulse separated from an end of the fourth current pulse by a rotor rotation of about 20 degrees. 4. A switched reluctance machine comprising: a stator further comprising a back iron and a set of stator poles connected to the back iron; a rotor, adjacent the stator, rotatively coupled to the stator and connected to a shaft; the rotor further comprising a set of rotor segments; a housing connected to the stator and adjacent the rotor; a set of stator windings alternately disposed between the set of stator poles; a set of phases, each phase comprising a subset of the set of stator windings; whereby selectively energizing the set of phases with a set of current pulses rotates the rotor with respect to the stator and the housing; a first rotor segment of the rotor segments including a first permanent magnet with a polarity that is substantially tangential to a direction of motion the rotor; the set of phases including the first phase, a second phase, as third phase, and a fourth phase; wherein the set of current pulses include a set of current pulses for the first phase, a set of current pulses for the second phase, a set of current pulses for the third phase, and a set of current pulses for the fourth phase; the circuit further configured to provide: the set of current pulses for the second phase offset from the set of current pulses of the first phase by about 15 degrees of rotor rotation and are of an opposite polarity with respect to the set of current pulses of the first phase; the set of current pulses for the third phase that are offset from the set of current pulses of the second phase by about 15 degrees of rotor rotation and are of an opposite polarity with respect to the set of current pulses of the second phase; and, the set of current pulses for the fourth phase that are offset from the set of current pulses of the third phase by about 15 degrees of rotor rotation and are of an opposite polarity with respect to the set of current pulses of the third phase.