Continuum robots with multi-scale motion through equilibrium modulation

What is claimed is: 1. A continuum robot comprising: a control disk; a bendable, rigid central backbone fixedly coupled to a center of the control disk; a first secondary backbone fixedly coupled the control disk at a defined distance from the center of the control disk, wherein the first secondary backbone is rigid, bendable, and hollow, wherein linear movement of the first secondary backbone relative to a base of the continuum robot causes a bending movement of the central backbone; and an equilibrium modulating wire slidably positioned inside the first secondary backbone. 2. The continuum robot of claim 1 , further comprising a plurality of control disks, the plurality of control disks including an end disk and at least one spacer disk, wherein the end disk is fixedly coupled to a distal end of the central backbone, and wherein the central backbone is fixedly coupled to a center of the at least one spacer disk. 3. The continuum robot of claim 2 , wherein the central backbone is fixedly coupled to the end disk and fixedly coupled to the at least one spacer disk such that, when the central backbone is straight, the control disk is parallel to the at least one spacer disk. 4. The continuum robot of claim 1 , further comprising a base disk, wherein the base disk includes a secondary backbone opening, wherein the first secondary backbone is positioned through the secondary backbone opening, wherein the secondary backbone opening limits lateral movement of the first secondary backbone relative to the base disk and allows linear movement of the first secondary backbone relative to the base disk, and wherein linear movement of the first secondary backbone relative to the base disk causes a bending of the central backbone and the first secondary backbone. 5. The continuum robot of claim 4 , wherein a first linear movement of the first secondary backbone relative to the base disk causes a first bending movement of the central backbone when the equilibrium modulating wire is inserted inside the first secondary backbone, and wherein the first linear movement of the first secondary backbone relative to the base disk causes a second bending movement of the central backbone when the equilibrium modulating wire is at least partially retracted from the first secondary backbone, wherein the second bending movement has a greater bending magnitude than the first bending movement. 6. The continuum robot of claim 1 , further comprising: a base disk; and a plurality of secondary backbones each fixedly coupled to the control disk at locations equidistantly distributed circumferentially around the center of the control disk, wherein the base disk includes a plurality of secondary backbone opening, wherein each secondary backbone of the plurality of secondary backbones is positioned through a different one of the plurality of secondary backbone openings, wherein each secondary backbone opening limits lateral movement of a corresponding secondary backbone relative to the base disk and allows linear movement of the corresponding secondary backbone relative to the base disk, and wherein coordinated linear movement of the secondary backbones causes the central backbone to bend to a target pose. 7. The continuum robot of claim 6 , wherein each secondary backbone of the plurality of secondary backbones is hollow, the continuum robot further comprising a plurality of equilibrium modulating wires each slidably positioned inside a different one of the plurality of secondary backbones, and wherein linear movement of each equilibrium modulating wire controllably alters a flexural rigidity of a secondary backbone. 8. The continuum robot of claim 1 , wherein linear movement of the equilibrium modulating wire relative to the first secondary backbone controllably alters a flexural rigidity of the first secondary backbone. 9. The continuum robot of claim 8 , wherein retracting the equilibrium modulating wire from the first secondary backbone reduces the flexural rigidity of the first secondary backbone. 10. The continuum robot of claim 1 , further comprising a robot actuator configured to controllably adjust linear movement of the first secondary backbone and to controllably adjust linear movement of the equilibrium modulating wire. 11. The continuum robot of claim 10 , further comprising an electronic controller configured to control movement of the central backbone by providing control signals to the robot actuator, wherein the electronic controller is configured to: determine a target pose for the central backbone; determine a target linear position of the first secondary backbone relative to a base disk of the continuum robot and a target linear position of the equilibrium modulating wire relative to the first secondary backbone needed to move the central backbone to the target pose; and operate the robot actuator to move the first secondary backbone and the equilibrium modulating wire based on the determined target linear positions. 12. The continuum robot of claim 10 , further comprising an end effector coupled to a distal end of the central backbone; and an electronic controller configured to control movement of the central backbone by providing control signals to the robot actuator, wherein the electronic controller is configured to: operate the robot actuator under macro-scale control by adjusting a linear position of the first secondary backbone relative to a base disk of the continuum robot until the end effector moves to an intermediate position within a threshold distance of a target position; and operate the robot actuator under micro-scale control by adjusting a linear position of the equilibrium modulating wire until the end effector moves from the intermediate position to the target position. 13. The continuum robot of claim 1 , wherein the equilibrium modulating wire is not fixedly coupled to the control disk and is not fixedly coupled to the base disk. 14. A method of adjustably controlling a pose of a continuum robot, the continuum robot including a base disk, a control disk, a bendable, rigid central backbone fixedly coupled to a center of the control disk, a first secondary backbone fixedly coupled to the control disk at a defined distance from the center of the control disk, wherein the a first secondary backbone is rigid, bendable, and hollow, wherein linear movement of the first secondary backbone relative to a base of the continuum robot causes a bending movement of the central backbone, and an equilibrium modulating wire slidably positioned inside the first secondary backbone, the method comprising: controlling a bending movement of the central backbone through direct actuation by controllably adjusting a linear position of first secondary backbone relative to the base of the continuum robot; and controlling the bending movement of the central backbone through indirect actuation by controllably adjusting a linear position of the equilibrium modulating wire relative to the first secondary backbone. 15. The method of claim 14 , wherein controlling the bending movement of the central backbone through indirect actuation includes adjusting a flexural rigidity of the first secondary backbone by inserting or retracting the equilibrium modulating wire into a hollow interior of the first secondary backbone. 16. The method of claim 14 , further comprising: determining, by an electronic processor, a target pose for the central backbone; and determining a target linear position of the first secondary backbone and a target linear position of the equilibrium modulating wire needed to move the