Propeller blade angle feedback arrangement and method

The invention claimed is: 1. A blade angle feedback assembly for a propeller of an aircraft engine, the propeller rotatable about a first axis and having propeller blades rotatable about respective second spanwise axes to adjust a blade angle thereof, the blade angle feedback assembly comprising: a feedback ring having a plurality of position markers disposed thereon; at least one sensor configured to provide feedback on the blade angle of the propeller blades by detecting a relative movement between the feedback ring and the at least one sensor; and at least one shielding element provided between the feedback ring and the propeller, the at least one shielding element configured to shield the feedback ring from electromagnetism. 2. The blade angle feedback assembly of claim 1 , wherein the feedback ring is coupled to the propeller to rotate with the propeller and to move along the first axis with adjustment of the blade angle, and the plurality of position markers is spaced around a circumference of the feedback ring, and further wherein the at least one sensor is configured to detect, as the feedback ring rotates about the first axis, passage of the plurality of position markers to provide feedback on the blade angle. 3. The blade angle feedback assembly of claim 1 , further comprising a plurality of rods coupled to the feedback ring and extending along a direction parallel to the first axis, the plurality of rods configured to support the feedback ring for longitudinal sliding movement along the first axis with adjustment of the blade angle, and further wherein the at least one shielding element comprises the plurality of rods being made from a non-conductive material. 4. The blade angle feedback assembly of claim 1 , further comprising a plurality of rods coupled to the feedback ring and extending along a direction parallel to the first axis, the plurality of rods configured to support the feedback ring for longitudinal sliding movement along the first axis with adjustment of the blade angle, and further wherein the feedback ring comprises a plurality of threaded inserts spaced around a circumference of the feedback ring and each configured to receive therein a given one of the plurality of rods, the at least one shielding element comprising the plurality of threaded inserts being made from a non-conductive material. 5. The blade angle feedback assembly of claim 4 , wherein the plurality of threaded inserts are made from a ceramic material. 6. The blade angle feedback assembly of claim 1 , wherein the at least one shielding element comprises the feedback ring being made from one of a non-conductive material and a material having resistivity to becoming magnetized. 7. The blade angle feedback assembly of claim 6 , wherein the feedback ring is made from a non-conductive polymer. 8. The blade angle feedback assembly of claim 1 , further comprising a plurality of rods coupled to the feedback ring and extending along a direction parallel to the first axis, the plurality of rods configured to support the feedback ring for longitudinal sliding movement along the first axis with adjustment of the blade angle, wherein the plurality of position markers is spaced around a circumference of the feedback ring and oriented at an angle relative to one another and relative to the first axis, the feedback ring further comprising a metallic inner ring configured to receive the plurality of rods therein and an outer ring configured to encapsulate the plurality of position markers, the at least one shielding element comprising the outer ring being made from a non-conductive material. 9. The blade angle feedback assembly of claim 8 , wherein the outer ring is made from a non-conductive polymer. 10. The blade angle feedback assembly of claim 1 , further comprising a plurality of rods coupled to the feedback ring and extending along a direction parallel to the first axis, the plurality of rods configured to support the feedback ring for longitudinal sliding movement along the first axis with adjustment of the blade angle, wherein the plurality of position markers is spaced around a circumference of the feedback ring and oriented at an angle relative to one another and relative to the first axis, the feedback ring further comprising a metallic inner ring configured to receive the plurality of rods therein and a metallic outer ring configured to support the plurality of position markers thereon, the at least one shielding element comprising a separating layer disposed between the inner ring and the outer ring, the separating layer made from a non-conductive material. 11. The blade angle feedback assembly of claim 1 , wherein the at least one shielding element comprises an insulator coating applied on one of the feedback ring and the at least one sensor for increasing a dielectric resistance of an air gap between the feedback ring and the at least one sensor. 12. The blade angle feedback assembly of claim 1 , wherein the feedback ring has first and second opposing faces and defines a root surface that extends and is circumscribed by the first and second faces, the plurality of position markers spaced around a circumference of the feedback ring, oriented at an angle relative to one another and relative to the first axis, and extending away from the root surface, the at least one shielding element comprising one of a plating and a coating applied on the root surface, the plating being a magnetic field blocking nano-plating and the coating being made of a material having resistivity to becoming magnetized. 13. An aircraft propeller system comprising: a propeller rotatable about a first axis and having propeller blades rotatable about respective second spanwise axes to adjust a blade angle thereof; a feedback ring having a plurality of position markers disposed thereon, the plurality of position markers spaced around a circumference of the feedback ring; and at least one shielding element provided between the feedback ring and the propeller, the at least one shielding element configured to shield the feedback ring from electromagnetism. 14. The aircraft propeller system of claim 13 , further comprising a plurality of rods coupled to the feedback ring and extending along a direction parallel to the first axis, the plurality of rods configured to support the feedback ring for longitudinal sliding movement along the first axis with adjustment of the blade angle, wherein the at least one shielding element comprises the plurality of rods being made from a non-conductive material. 15. The aircraft propeller system of claim 13 , further comprising a plurality of rods coupled to the feedback ring and extending along a direction parallel to the first axis, the plurality of rods configured to support the feedback ring for longitudinal sliding movement along the first axis with adjustment of the blade angle, wherein the feedback ring comprises a plurality of threaded inserts spaced around the circumference of the feedback ring and each configured to receive therein a given one of the plurality of rods, the at least one shielding element comprising the plurality of threaded inserts being made from a non-conductive material. 16. The aircraft propeller system of claim 13 , wherein the at least one shielding element comprises the feedback ring being made from one of a non-conductive material and a material having resistivity to becoming magnetized. 17. The aircraft propeller system of claim 13 , further comprising a plurality of rods coupled to the feedback ring and extending along a direction parallel to the first axis, the plurality