Robotic fingers and end effectors including same

1 . A robotic end effector comprising: a finger extending from a proximal end to a distal end along a finger axis, the finger comprising: a first phalanx proximate the proximal end; a second phalanx proximate the distal end; a knuckle joint including at least one vertebra interposed between and separating the first and second phalanxes, wherein: the knuckle joint is configured to permit the second phalanx to pivot relative to the first phalanx about a pivot axis transverse to the finger axis; and each vertebra has an axial thickness extending along the finger axis and a lateral width extending perpendicular to its axial thickness, and its lateral width is greater than its axial thickness; and at least one actuator to move the second phalanx relative to the first phalanx about the pivot axis. 2 . The robotic end effector of claim 1 wherein each of the first and second phalanxes has a phalanx length that is at least 2 times the axial thickness of each of the vertebrae. 3 . The robotic end effector of claim 1 wherein the lateral width of each of the vertebrae is at least 1.5 times its axial thickness. 4 . The robotic end effector of claim 1 wherein each of the vertebrae has a height perpendicular to each of its axial thickness and its lateral width, and the axial thickness of the vertebra varies across the height of the vertebra. 5 . The robotic end effector of claim 1 wherein at least one of the vertebrae includes a nonplanar bearing surface that engages an adjacent bearing surface of one of the first phalanx, the second phalanx, and an adjacent vertebra. 6 . The robotic end effector of claim 5 wherein the bearing surface has at least one substantially planar section. 7 . The robotic end effector of claim 5 wherein the bearing surface includes: an outer stop face configured to limit rotation of the first phalanx about the pivot axis in a first bending direction; and an angled inner face disposed at an oblique angle to the outer stop face to permit rotation of the first phalanx about the pivot axis in a second bending direction opposite the first bending direction. 8 . The robotic end effector of claim 7 wherein the bearing surface further includes a neutral face located between the outer stop face and the inner angled face and disposed at an oblique angle to the outer stop face and the angled inner face. 9 . The robotic end effector of claim 1 wherein the at least one vertebra includes a plurality of vertebrae serially arranged between the first phalanx and second phalanxes. 10 . The robotic end effector of claim 9 wherein the at least one vertebra includes at least three vertebrae serially arranged between the first phalanx and second phalanxes. 11 . The robotic end effector of claim 9 wherein each of the plurality of vertebrae includes a nonplanar bearing surface that engages an adjacent bearing face of one of the first phalanx, the second phalanx, and an adjacent vertebra. 12 . The robotic end effector of claim 9 wherein at least two of the vertebrae have different axial thicknesses from one another. 13 . The robotic end effector of claim 1 including: a third phalanx proximate the distal end of the finger; a second knuckle joint including at least one vertebra interposed between and separating the second and third phalanxes, wherein: the second knuckle joint is configured to permit the third phalanx to pivot relative to the second phalanx about a second pivot axis transverse to the finger axis; and each vertebra of the second knuckle joint has an axial thickness and a lateral width extending perpendicular to its axial thickness, and its lateral width is greater than its axial thickness; and wherein the at least one actuator is operable to move the third phalanx relative to the second phalanx about the second pivot axis. 14 . The robotic end effector of claim 1 including an elongate, flexible guide member extending from the first phalanx to the second phalanx and through the at least one vertebra to flexibly couple the first and second phalanxes and the at least one vertebra and retain the at least one vertebra between the first and second phalanxes. 15 . The robotic end effector of claim 14 wherein the guide member has a Young's modulus of less than about 2.4 GPa at 23 degrees Celsius. 16 . The robotic end effector of claim 1 including: a tendon cable associated with the at least one actuator for moving the second phalanx relative to the first phalanx about the pivot axis; wherein the tendon cable extends through the at least one vertebra and applies an axially compressive load to the first phalanx, the second phalanx and the at least one vertebra to hold the first phalanx, the second phalanx and the at least one vertebra together and in contact with one another. 17 . The robotic end effector of claim 16 including a tensioning mechanism to maintain the axially compressive load. 18 . The robotic end effector of claim 16 wherein the tensioning mechanism includes a spring applying a biasing load to the tendon cable. 19 . The robotic end effector of claim 1 including: first and second tactile sensors mounted on the first and second phalanxes, respectively; wherein the at least one vertebra does not or do not include tactile sensors mounted thereon. 20 . The robotic end effector of claim 19 including electrical wires electrically connected to the second tactile sensor and extending from the second phalanx and through the at least one vertebra. 21 . The robotic end effector of claim 1 wherein the at least one vertebra is or are formed of a polymeric material. 22 .- 42 . (canceled)