Encapsulated soft-lead capacitance probe for a gas turbine engine

What is claimed is: 1. A fan case assembly for a gas turbine engine, comprising: a fan with a fan blade rotatable within a fan case with a liner therein, wherein the liner lines the fan case and is thermally conforming, the liner and the fan blade thermally expand or contract radially and define a gap between the liner and a tip of the fan blade; and a gap measuring assembly comprising a capacitance probe mounted to the liner that travels with the liner as the liner expands and or contracts, the capacitance probe being able to sense the gap between the liner and the fan blade tip of the fan blade as the fan blade tip passes relative to the liner; the capacitance probe including: a circuit board sensor mounted to the liner; a housing including an insulating material, and the circuit board sensor including a capacitor and a metallic plate, the metallic plate disposed within the insulating material and in electronic communication with the circuit board sensor; a soft lead extending from the housing and being embedded in the liner and being flexible and movable with the liner as the liner thermally expands, the soft lead carries electronic information from the circuit board sensor; and the housing having a base and a cap, the base having a notch through which the soft lead passes, the housing connected to the liner so that the circuit board sensor is modifiable without damaging the capacitance probe, including adding, removing or adjusting capacitors on the circuit board sensor. 2. The fan case assembly of claim 1 , wherein the capacitance probe includes an annular ring pad in electronic communication with the capacitor and operatively associated with the metallic plate. 3. The fan case assembly of claim 1 , wherein the capacitance probe includes plural capacitors and the annular ring pad is in electronic communication with the plural capacitors. 4. The fan case-assembly of claim 1 , wherein the liner is able to expand in response to thermal or mechanical changes. 5. The fan case assembly of claim 1 , wherein the insulating material for capacitance probe is a polymer. 6. The fan case assembly of claim 1 , wherein the insulating material for the capacitance probe is a ceramic. 7. The fan case assembly of claim 1 , wherein the housing for the capacitance probe is made from an electrically conductive material. 8. The fan case assembly of claim 4 , wherein the gap measuring assembly is able to sense a distance at which the fan blade tip passes relative to the liner. 9. A gas turbine engine, comprising; a fan located at an axially forward end of the gas turbine engine and axially forward of a compressor, the fan with a fan blade rotatable within a fan case with a liner therein, wherein the liner lines the fan case and is thermally conforming, the liner and fan thermally expand or contract radially and define a gap between the liner and a tip of the fan blade; the compressor located axially forward of a turbine; the turbine mechanically connected to the fan and the compressor; a gap measuring assembly comprising: a capacitance probe mounted to the liner that travels with the liner as the liner expands and or contracts, the capacitance probe being able to sense the gap between the liner and the fan blade tip of the fan blade as the fan blade tip passes relative to the liner; the capacitance probe including: a circuit board sensor mounted to the liner; a housing including an insulating material, and the circuit board sensor including a capacitor and a metallic plate, the metallic plate disposed within the insulating material and in electronic communication with the circuit board sensor; a soft lead extending from the housing and being embedded in the liner and being flexible and movable with the liner as the liner thermally expands, the soft lead carries electronic information from the circuit board sensor; and the housing having a base and a cap, the base having a notch through which the soft lead passes, the housing connected to the liner so that the circuit board sensor is modifiable without damaging the capacitance probe, including adding, removing or adjusting capacitors on the circuit board sensor. 10. The gas turbine engine of claim 9 , wherein the capacitance probe includes an annular ring pad in electronic communication with the capacitor and operatively associated with the metallic plate. 11. The gas turbine engine of claim 9 , wherein the capacitance probe includes plural capacitors and the annular ring pad is in electronic communication with the plural capacitors. 12. The gas turbine engine of claim 9 , wherein the insulating material is a polymer. 13. The gas turbine engine of claim 9 , wherein the insulating material is a ceramic. 14. The gas turbine engine of claim 9 , wherein the housing is made from an electrically conductive material. 15. A method for measuring clearance of a fan blade tip, of a fan blade connected to a fan, relative to a liner that lines a fan case of a gas turbine engine, comprising: attaching a capacitance probe to the liner, the capacitance probe including: a circuit board sensor mounted to the liner; a housing including an insulating material, and the circuit board sensor including a capacitor and a metallic plate, the metallic plate disposed within the insulating material and in electronic communication with the circuit board sensor; a soft lead extending from the housing and being embedded in the liner and movable with the liner as the liner thermally expands, the soft lead carries electronic information from the circuit board sensor; and the housing having a base and a cap, the base having a notch through which the soft lead passes, the housing connected to the liner so that the circuit board sensor is modifiable without damaging the capacitance probe, including adding, removing or adjusting capacitors on the circuit board sensor; rotating the fan about a central longitudinal axis; and sensing a distance between the fan blade tip and the capacitance probe when the fan blade tip travels past the sensor.