Piston cap

What is claimed is: 1. A brake system comprising: a pressure plate defining a contact surface, wherein the pressure plate is configured to compress a disc stack of the brake system; and a piston configured to cause the pressure plate to compress the disc stack, the piston comprising: a piston body configured to translate along a piston axis; and a piston cap defining a cap face intersected by the piston axis and defining a perimeter around the piston axis, wherein the cap face defines an inner surface section intersected by the piston axis, an outer surface section adjacent the perimeter, and a medial surface section between the inner surface section and the outer surface section, wherein the medial surface section defines convex surface defining a curvature, wherein the piston body is configured to compress the cap face against the contact surface of the pressure plate to cause the pressure plate to compress the disc stack, wherein the convex surface is configured to reduce the curvature when the piston body compresses the cap face against the contact surface, wherein the piston cap defines a back face opposite the cap face and defines a thickness substantially parallel to the piston axis from the cap face to the back face, and wherein the thickness increases as a distance from the piston axis toward the perimeter increases over at least a portion of the piston cap. 2. The brake system of claim 1 , wherein the inner surface section is configured to be substantially parallel to the contact surface when the cap face is displaced from the contact surface. 3. The brake system of claim 1 , wherein the piston cap is configured to elastically deform such that the inner surface section and the medial surface section contact the contact surface when the piston body compresses the cap face against the contact surface. 4. The brake system of claim 1 , wherein the cap face defines a concave surface defining a second curvature, wherein the concave surface is configured to reduce the second curvature when the piston body compresses the cap face against the contact surface. 5. The brake system of claim 4 , wherein the outer surface section defines the concave surface. 6. The brake system of claim 1 , wherein the back face defines a back perimeter around the piston axis, and wherein the piston body is configured to exert a force on the back perimeter to cause the piston body to compress the cap face against the contact surface. 7. The brake system of claim 1 , wherein the pressure plate includes a plate body layered by a coating, wherein the coating defines the contact surface, and wherein the coating is more brittle than the plate body. 8. The brake system of claim 1 , wherein: the piston body defines a piston wall having an inner surface facing the piston axis and an outer surface opposite the inner surface; the inner surface and the back face define a piston cavity intersected by the piston axis; and the piston wall is configured to exert a force on the back face to cause the piston body to compress the cap face against the contact surface. 9. The brake system of claim 1 , wherein the piston body and the piston cap define a cavity within the piston, wherein the piston cap is between the contact surface and the cavity, and wherein the piston cap is configured to deflect towards the cavity when the piston body compresses the cap face against the contact surface. 10. The brake system of claim 1 , wherein the brake system is configured to cause the pressure plate to exert a reaction force on the cap face when the piston body compresses the cap face against the contact surface. 11. The brake system of claim 1 , wherein the pressure plate comprises a carbon composite material. 12. The brake system of claim 1 , further comprising the disc stack, wherein the disc stack includes at least one rotor disc and at least one stator disc, wherein the brake system is configured to cause a friction surface on the rotor disc to contact a friction surface on the stator disc when the piston body compresses the cap face against the contact surface. 13. The brake system of claim 1 , wherein the disc stack includes a stator disc configured to remain rotationally stationary with respect to a torque tube of the brake system and a rotor disc configured to rotate relative to the torque tube of the brake system. 14. A brake system comprising: a piston defining a piston axis and configured to cause a pressure plate of the brake system to compress a disc stack of the brake system, the piston comprising: a piston cap defining a cap face intersected by the piston axis and a back face opposite the cap face, wherein the cap face defines a perimeter around the piston axis and the back face defines a back perimeter around the piston axis, wherein the cap face defines an inner surface section intersected by the piston axis, an outer surface section adjacent the perimeter, and a medial surface section between the inner surface section and the outer surface section, and wherein the medial surface section defines a convex surface defining a curvature, wherein the piston cap defines a thickness substantially parallel to the piston axis from the cap face to the back face; and a piston body configured to translate along the piston axis, wherein the piston body is configured to exert a force on the back perimeter to compress the cap face against a contact surface of the pressure plate, wherein the convex surface is configured to reduce the curvature when the piston body compresses the cap face against the contact surface, and wherein the thickness increases as a distance from the piston axis toward the back perimeter increases over at least a portion of the piston face. 15. The brake system of claim 14 , wherein the piston body and the piston cap define a cavity within the piston, wherein the piston cap is between the contact surface and the cavity, and wherein the piston cap is configured to deflect towards the cavity when the piston body compresses the cap face against the contact surface. 16. The brake system of claim 14 , wherein the inner surface section is configured to be substantially parallel to the contact surface when the cap face is displaced from the contact surface. 17. The brake system of claim 14 , wherein the outer surface section defines a concave surface. 18. A method, comprising: translating a piston body of a piston along a piston axis defined by the piston toward a contact surface of a pressure plate; translating a piston cap having a cap face toward the contact surface using the translation of the piston body, the cap face defining an inner surface section intersected by the piston axis, an outer surface section adjacent a perimeter of the cap face, and a medial surface section between the inner surface section and the outer surface section, wherein the medial surface section defines a convex surface defining a curvature, and the piston cap defining a back face opposite the cap face, wherein the piston cap defines a thickness substantially parallel to the piston axis from the cap face to the back face, wherein the thickness increases as a distance from the piston axis toward the perimeter of the cap face increases; reducing the curvature of the convex surface by compressing the cap face against the contact surface using the piston body; and compressing a disc stack using the pressure plate when the cap face is compressed against the contact surface. 19. The method of claim 18 , further comprising exerting a force on a back perimeter of th