Short circuit fault tolerant permanent magnet machine

The invention claimed is: 1. A permanent magnet (PM) machine comprising: a rotor comprising 10*N permanent magnets disposed about an axis of rotation; and a stator assembly comprising: an annular stator body comprising 24*N stator teeth disposed circumferentially about the stator body, and extending radially inward from the stator body relative to a central axis of the stator body, wherein the stator teeth define 24*N stator slots, each stator slot disposed between adjacent stator teeth; a first set of 16*N coil sides, wherein each coil side of the first set of coil sides is disposed in a respective stator slot of a first set of the 24*N stator slots, wherein each of the 24*N stator slots is configured to receive two coil sides disposed radially adjacent to one another relative to the central axis of the stator body, wherein the first set of coil sides correspond to a first power phase, wherein the first set of coil sides are electrically coupled to one another by a first set of 16*N respective end coils, and wherein the first set of coil sides are separated from one another by two stator teeth; and a plurality of sintered iron magnetic wedges, each disposed at an opening of at least one stator slot of the 24*N stator slots; wherein N is a positive integer, and wherein the PM machine has a fractional number of stator slots, per a number of permanent magnet poles. 2. The PM machine of claim 1 , wherein a relative magnetic permeability of the sintered iron magnetic wedges is 10 or greater. 3. The PM machine of claim 1 , wherein each of the plurality of sintered iron magnetic wedges comprises a coating of at least one material or combination materials or composite material of metal, thermoset, or thermoplastic. 4. The PM machine of claim 1 , wherein the stator assembly comprises: a second set of 16*N coil sides, wherein each coil side of the second set of coil sides is disposed in a respective stator slot of a second set of the 24*N stator slots, wherein the second set of coil sides correspond to a second power phase, wherein the second set of coil sides are electrically coupled to one another by a second set of 16*N respective end coils, and wherein the second set of coil sides are separated from one another by two stator teeth; and a third set of 16*N coil sides, wherein each coil side of the third set of coil sides is disposed in a respective stator slot of a third set of the set of 24*N stator slots, wherein the third set of coil sides correspond to a third power phase, wherein the third set of coil sides are electrically coupled to one another by a third set of 16*N respective end coils, and wherein the third set of coil sides are separated from one another by two stator teeth. 5. The PM machine of claim 1 , wherein the first set of coil sides are configured to be inserted into the respective openings of the first set of the 24*N stator slots, and brazed. 6. The PM machine of claim 1 , wherein each coil side of the first set of coil sides comprises a strip of copper. 7. The PM machine of claim 1 , wherein adjacent coil sides disposed within at least one of the 24*N stator slots are separated by an insulator. 8. The PM machine of claim 4 , wherein the first, second, and third sets of coil sides are arranged, as in claim 4 , such that the PM machine may sustain a 3-phase short circuit current indefinitely. 9. A permanent magnet (PM) machine comprising: a rotor comprising: a rotor hub; and 10*N permanent magnets disposed about the rotor hub; a stator assembly comprising: an annular stator body comprising 24*N stator teeth disposed circumferentially about the stator body, and extending radially inward from the stator body relative to a central axis of the stator body, wherein the 24*N stator teeth define 24*N stator slots, each stator slot disposed between adjacent stator teeth, such that each stator slot of the 24*N stator slots comprises: an inside position; and an outside position disposed radially outside of the inside position relative to the central axis of the stator body; a first set of 16*N coil sides, wherein each coil side of the first set of coil sides is disposed in the inside position or the outside position of a respective stator slot of a first set of the 24*N stator slots, wherein the first set of coil sides correspond to a first power phase, wherein the first set of coil sides are electrically coupled to one another by a first set of 16*N respective end coils, and wherein the first set of coil sides are separated from one another by two stator teeth; and a plurality of sintered iron magnetic wedges, each disposed at an opening of at least one stator slot of the 24*N stator slots; wherein N is a positive integer, and wherein the PM machine has a fractional number of stator slots, per a number of permanent magnet poles. 10. The PM machine of claim 9 , wherein the first set of coil sides are configured to be inserted into the respective openings of the first set of the 24*N stator slots, and brazed. 11. The PM machine of claim 9 , wherein a relative magnetic permeability of the sintered iron magnetic wedges is 10 or greater. 12. The PM machine of claim 9 , wherein the inside position and the outside position of each stator slot are separated by an insulator. 13. A permanent magnet (PM) machine comprising: a rotor comprising: a rotor hub; and a set of 10*N permanent magnet poles disposed about the rotor hub; a stator assembly comprising: an annular stator body comprising 24*N stator teeth disposed circumferentially about the stator body, and extending radially inward from the stator body relative to a central axis of the stator body, wherein the stator teeth define 24*N stator slots, each stator slot disposed between adjacent stator teeth, such that each stator slot the 24*N of stator slots comprise: an inside position; and an outside position disposed radially outside of the inside position relative to the central axis of the stator body; a first set of 16*N coil sides, wherein each coil side of the first set of coil sides is disposed in the inside position or the outside position of a respective stator slot of a first set of the stator slots, wherein the first set of 16*N coil sides correspond to a first power phase, wherein the first set of 16*N coil sides are electrically coupled to one another by a first set of end coils, and wherein the first set of 16*N coil sides are separated from one another by two stator teeth; a second set of 16*N coil sides, wherein each coil side of the second set of coil sides is disposed in the inside position or the outside position of a respective stator slot of a second set of the stator slots, wherein the second set of 16*N coil sides correspond to a second power phase, wherein the second set of 16*N coil sides are electrically coupled to one another by a second set of end coils, and wherein the second set of 16*N coil sides are separated from one another by two stator teeth; a third set of 16*N coil sides, wherein each coil side of the third set of coil sides is disposed in the inside position or the outside position of a respective stator slot of a third set of the stator slots, wherein the third set of 16*N coil sides correspond to a third power phase, wherein the third set of 16*N coil sides are electrically coupled to one another by a third set of end coils, and wherein the third set of 16*N coil sides are separated from one another by two stator teeth; and a plurality of sintered iron magnetic wedges, each disposed at an opening of each of the plurality of stator slots; wherein N is a positive integer; wherein the PM machine has a fractional number of stator slots