Mutli-excitaton resolver and related techniques

What is claimed is: 1 . A rotor for use in a resolver, the rotor comprising: a rotor substrate having first and second opposing surfaces; and first and second sets of conductors having a sinusoidally varying shape disposed on at least one of the first and second opposing surfaces of the rotor with the first set of conductors arranged to provide a single-speed resolver excitation circuit and the second set of conductors arranged to provide a multi-speed resolver excitation circuit. 2 . The rotor of claim 1 wherein: (a) the first set of conductors comprises: a first conductor which forms a first portion of a single-speed excitation circuit; a second conductor which forms a second portion of the single-speed excitation circuit with the first conductor being electrically separate from the second conductor; a first transmission signal conductor coupled to the first conductor; and a second, different transmission signal conductor, electrically separate from the first transmission signal path coupled to the second conductor. 3 . The rotor of claim 1 wherein: (a) the second set of conductors comprises: a first plurality of conductors which form a first portion of the multi-speed excitation circuit; a second plurality of conductors which form a second portion of the multi-speed excitation circuit with the second plurality of conductors being electrically isolated from the first plurality of conductors; a first transmission signal path coupled to the first plurality of conductors which form the first portion of the multi-speed excitation circuit; and a second transmission signal path coupled to the second plurality of conductors which form the second portion of the multi-speed excitation circuit. 4 . The rotor of claim 1 wherein: (a) the first set of conductors disposed on the rotor comprises: a first conductor which forms a first portion of a single-speed excitation circuit; a second conductor which forms a second portion of the single-speed excitation circuit with the first and second conductors electrically separate; a first transmission signal path coupled to the first conductor; and a second, different transmission signal path, electrically separate from the first transmission signal path coupled to the second conductor. (b) the second set of conductors disposed on the rotor comprises: a first plurality of conductors which form a first portion of the multi-speed excitation circuit; a second plurality of conductors which form a second portion of the multi-speed excitation circuit with the second plurality of conductors being electrically isolated from the first plurality of conductors; a first transmission signal path coupled to the first plurality of conductors which form the first portion of the multi-speed excitation circuit; and a second transmission signal path coupled to the second plurality of conductors which form the second portion of the multi-speed excitation circuit. 5 . The rotor of claim 1 wherein the first transmission signal path is provided having an annular shape. 6 . The rotor of claim 1 wherein the second transmission signal path is provided having an annular shape. 7 . The rotor of claim 2 wherein the first set of conductors are disposed on the same surface of the rotor substrate. 8 . The rotor of claim 3 wherein the second set of conductors are disposed on the same surface of the rotor substrate. 9 . The rotor of claim 1 wherein the first and second sets of conductors are disposed on the same surface of the rotor substrate. 10 . The rotor of claim 1 wherein: the first set of conductors are disposed on a first one of the first and second opposing surfaces of the rotor substrate; and the second set of conductors are disposed on a second one of the first and second opposing surfaces of the rotor substrate. 11 . A multi-excitation resolver comprising: a rotor substrate having first and second opposing surfaces with first and second sets of conductors disposed on at least one of the first and second opposing surfaces of the rotor with the first set of conductors arranged to provide a one-speed resolver excitation circuit and the second set of conductors arranged to provide a multi-speed resolver excitation circuit; and a stator having first and second opposing surfaces, with third and fourth sets of conductors disposed on at least one of the first and second opposing surfaces of the stator with the third set of conductors arranged to provide a one-speed resolver output pickup circuit and the fourth set of conductors arranged to provide a multi-speed resolver output pickup circuit wherein a first one of the first and second opposing surfaces of the stator are disposed over a first one of the first and second surfaces of the rotor such that a capacitive gap exists between at least some of the first and second conductors on the rotor and at least some of the third and fourth conductors of the stator. 12 . The multi-excitation resolver of claim 11 , wherein: the rotor is movable relative to the stator; and in response to relative movement between the rotor and the stator, at least portions of the first and second sets of conductors overlap at least portions of the third and fourth sets of conductors to form one or more overlapping areas having a sinusoidally varying shape. 13 . The stator of claim 11 wherein the one-speed resolver output pickup circuit is at an offset between 80-100 degrees from the multi-speed resolver output pickup circuit. 14 . The multi-excitation resolver of claim 11 wherein: (a) the first set of conductors on the rotor comprise: a first conductor which forms a first portion of a single-speed excitation circuit; a second conductor which forms a second portion of the single-speed excitation circuit with the first and second conductors being electrically separate; a first transmission conductor coupled to the first conductor; and a second, transmission conductor, electrically separate from the first transmission signal path coupled to the second conductor. 15 . The multi-excitation resolver of claim 11 wherein: (a) the second set of conductors comprises: a first plurality of conductors which form a first portion of the multi-speed excitation circuit; a second plurality of conductors which form a second portion of the multi-speed excitation circuit with the second plurality of conductors being electrically isolated from the first plurality of conductors; a first transmission signal conductor coupled to the first plurality of conductors which form the first portion of the multi-speed excitation circuit; and a second transmission signal conductor coupled to the second plurality of conductors which form the second portion of the multi-speed excitation circuit. 16 . The multi-excitation resolver of claim 11 wherein: (a) the first set of conductors disposed on the rotor comprises: a first conductor which forms a first portion of a single-speed excitation circuit; a second conductor which forms a second portion of the single-speed excitation circuit with the first and second conductors are electrically separate; a first transmission signal path coupled to the first conductor; and a second, different transmission signal conductor, electrically separate from the first transmission signal path coupled to the second conductor. one or more shielding conductors disposed about the first set of conductors; (b) the second set of conductors disposed on the rotor comprises: a first plurality of conductors which form a first portion of the multi-speed excitation circuit;