Radially embedded permanent magnet rotor and methods thereof

What is claimed is: 1 . An electric machine comprising: a machine housing; a stator disposed at least partially within said machine housing, said stator comprising at least one tooth and an aluminum winding wound around said at least one tooth; and a rotor disposed at least partially within said machine housing, said rotor configured to rotate with respect to said stator, wherein said rotor is a radially embedded permanent magnet rotor configured to generate an amount of flux to reduce efficiency loss due to said aluminum winding, said rotor comprising: at least one permanent magnet; a substantially cylindrical rotor core comprising an outer edge and an inner edge defining a central opening, said rotor core having a radius R, said rotor further comprising at least one pole and at least one radial aperture extending radially into said rotor core from said outer edge to a predetermined depth less than said radius, said at least one radial aperture configured to receive said at least one permanent magnet; and at least one protrusion extending into said at least one radial aperture, said at least one protrusion positioned substantially along a bottom of said at least one radial aperture and configured to facilitate retention of said at least one permanent magnet within said at least one radial aperture. 2 . The electric machine of claim 1 , further comprising a shaft extending through said central opening, said at least one permanent magnet positioned within said rotor core radially about said shaft and an axis of rotation of said rotor core. 3 . The electric machine of claim 1 , wherein a radially outer surface of said at least one radially embedded permanent magnet comprises a radially outer surface of said radially embedded permanent magnet rotor. 4 . The electric machine of claim 1 , wherein said at least one permanent magnet is a ferrite permanent magnet. 5 . The electric machine of claim 4 , wherein said at least one permanent magnet is fabricated from a magnetic material with remnance of at least 0.4 T, wherein said at least one permanent magnet is configured to generate an amount of flux to reduce efficiency loss due to said aluminum winding. 6 . The electric machine of claim 1 , wherein said at least one protrusion comprises a first pair of protrusions and a second pair of protrusions, said first and second pair of protrusions extending into said at least one radial aperture from opposed walls of said radial aperture. 7 . The electric machine of claim 6 , wherein said first pair of protrusions is positioned substantially at a bottom of said at least one radial aperture and said second pair of protrusions is positioned substantially along said outer edge of said rotor core. 8 . The electric machine of claim 1 , wherein said winding is at least one of a concentrated type winding and an overlapped type winding. 9 . An electric machine comprising: a machine housing; a stator disposed at least partially within said machine housing, said stator comprising at least one tooth and an aluminum winding wound around said at least one tooth; and a rotor disposed at least partially within said machine housing, said rotor configured to rotate with respect to said stator, wherein said rotor is a radially embedded permanent magnet rotor configured to generate an amount of flux to reduce efficiency loss due to said aluminum winding said rotor comprising: at least one permanent magnet; a substantially cylindrical rotor core comprising an outer edge and an inner edge defining a central opening, said rotor core having a radius R, said rotor further comprising at least one pole and at least one radial aperture extending radially into said rotor core from said outer edge to a predetermined depth less than said radius, said at least one radial aperture configured to receive said at least one permanent magnet; and at least one protrusion extending into said at least one radial aperture, said at least one protrusion positioned substantially along a bottom of said at least one radial aperture and configured to facilitate retention of said at least one permanent magnet within said at least one radial aperture, wherein said predetermined depth of each of said plurality of radial apertures is between a minimum depth defined by the equation D min = ( π * R ) n , and a maximum depth defined by the equation D max = R - 0.5  t tan ( 180 n ) , wherein n is the number of poles of the rotor core and t is the thickness of said at least one permanent magnet. 10 . The electric machine of claim 9 , wherein a radially outer surface of said at least one radially embedded permanent magnet comprises a radially outer surface of said radially embedded permanent magnet rotor. 11 . The electric machine of claim 9 , wherein said at least one permanent magnet is a ferrite permanent magnet. 12 . The electric machine of claim 11 , wherein said at least one permanent magnet is fabricated from a magnetic material with remnance of at least 0.4 T, wherein said at least one permanent magnet is configured to generate an amount of flux to reduce efficiency loss due to said aluminum winding. 13 . The electric machine of claim 9 , wherein said at least one pole comprises a radially inner wall including a first continuous circular arc extending between a pair of adjacent radial apertures and a radially outer wall comprising a second continuous circular arc extending between said adjacent radial apertures. 14 . The electric machine of claim 13 , wherein at least one of said radially inner wall and said radially outer wall at least partially form said at least one protrusion, wherein said radially inner wall is substantially concentric with said radially outer wall. 15 . The electric machine of claim 9 , wherein at least one of said at least one radial aperture and said permanent magnet is tapered. 16 . The electric machine of claim 9 , wherein said at least one protrusion comprises a first pair of protrusions and a second pair of protrusions, said first and second pair of protrusions extending into said at least one radial aperture from opposed walls of said radial aperture. 17 . The electric machine of claim 16 , wherein said first pair of protrusions is positioned substantially at a bottom of said at least one radial aperture and said second pair of protrusions is positioned substantially along said outer edge of said rotor core.