Methods and systems for planning a body position of a robotic device

What is claimed is: 1. A method comprising: receiving, by a computing device, a reference step path that comprises a plurality of spatial points that each define a predetermined step location for an end component of a robotic device, wherein the robotic device has a plurality of appendages and the plurality of appendages are connected to a body of the robotic device, wherein the end component is connected to a distal end of a given appendage of the plurality of appendages; receiving, by the computing device, a set of constraints comprising a length of the given appendage and a gravitational force experienced by the body of the robotic device; receiving, by the computing device, a predetermined height and a predetermined pitch of the body for the robotic device to maintain a balance; assigning, by the computing device, a cost to each of a height of the body, a height acceleration of the body, and a pitch acceleration of the body; determining, by the computing device, a new height and a new pitch of the body that reduces the height acceleration and the pitch acceleration of the body when the end component moves along the reference step path, based on i) the reference step path, ii) the set of constraints, iii) the predetermined height and the predetermined pitch of the body and iv) the cost to each of the height of the body, the height acceleration of the body, and the pitch acceleration of the body; and instructing the robotic device to actuate the plurality of appendages to achieve the new height and the new pitch of the body when the end component moves along the reference step path. 2. The method of claim 1 , further comprising: assigning, by the computing device, a cost to each of a center of pressure that indicates an amount of force on the end component, a capture point that indicates a position on the surface based on a velocity of the body and a center of mass of the body, a forward acceleration of the body, and a lateral acceleration of the body; determining, by the computing device, a new forward position and a new lateral position of the robotic device that reduces the height acceleration and the pitch acceleration of the body when the end component moves along the reference step path, based on i) the reference step path, ii) the set of constraints, iii) the predetermined height and the predetermined pitch of the body and iv) the cost to each of the height of the body, the height acceleration of the body, the pitch acceleration of the body, the center of pressure, the capture point, the forward acceleration of the body, and the lateral acceleration of the body; and instructing the robotic device to actuate the plurality of appendages to achieve the new forward position and new lateral position when the end component moves along the reference step path. 3. The method of claim 1 , wherein the set of constraints further comprises a center of pressure constraint that requires a force put on the end component to be greater than or equal to zero. 4. The method of claim 1 , further comprising: assigning, by the computing device, a cost to each of a front hip joint height and a hind hip joint height, wherein each hip joint is defined as a connection point between a given appendage and the body of the robotic device; and determining, by the computing device, a new height and a new pitch of the body that reduces the height acceleration and the pitch acceleration of the body when the end component moves along the reference step path, based on i) the reference step path, ii) the set of constraints, iii) the predetermined height and the predetermined pitch of the body and iv) the cost to each of the front hip joint height, the hind hip joint height, the height acceleration of the body, and the pitch acceleration of the body. 5. The method of claim 1 , further comprising: determining, by the computing device, a plurality of hip joint heights that reduce the height acceleration and the pitch acceleration of the body when the end component moves along the reference step path, based on i) the reference step path, ii) the set of constraints, iii) the predetermined height and the predetermined pitch of the body and iv) the cost to each of the height of the body, the height acceleration of the body, and the pitch acceleration of the body, wherein each given hip joint height is defined as a height of a connection point between a given appendage and the body of the robotic device; and instructing the robotic device to actuate the plurality of appendages to achieve the plurality of hip joint heights when the end component moves along the reference step path. 6. The method of claim 1 , further comprising: receiving, by the computing device, a x-coordinate and a y-coordinate of the predetermined step location of the end component from a robotic gait system that determines the reference step path; and receiving, by the computing device, a z-coordinate of the predetermined step location of the end component from a robotic vision system that comprises a processor and a camera feed from a field of view of the robotic device. 7. The method of claim 1 , further comprising: assigning a value of the cost based on avoiding a physical limit of the set of constraints and preventing two or more constraints within the set of constraints from conflicting while reducing the height acceleration and the pitch acceleration. 8. The method of claim 1 , further comprising: assigning a value of the cost based on a difference between the predetermined height of the body and the new height of the body. 9. A non-transitory computer readable medium having stored thereon instructions that, upon execution by a computing device, cause the computing device to perform functions comprising: receiving a reference step path that comprises a plurality of spatial points that each define a predetermined step location for an end component of a robotic device, wherein the robotic device has a plurality of appendages and the plurality of appendages are connected to a body of the robotic device, wherein the end component is connected to a distal end of a given appendage of the plurality of appendages; receiving a set of constraints comprising a length of the given appendage and a gravitational force experienced by the body of the robotic device; receiving a predetermined height and a predetermined pitch of the body for the robotic device to maintain a balance; assigning a cost to each of a height of the body, a height acceleration of the body, and a pitch acceleration of the body; determining a new height and a new pitch of the body that reduces the height acceleration and the pitch acceleration of the body when the end component moves along the reference step path, based on i) the reference step path, ii) the set of constraints, iii) the predetermined height and the predetermined pitch of the body and iv) the cost to each of the height of the body, the height acceleration of the body, and the pitch acceleration of the body; and instructing the robotic device to actuate the plurality of appendages to achieve the new height and the new pitch of the body when the end component moves along the reference step path. 10. The non-transitory computer readable medium of claim 9 , the functions performed further comprising: assigning a cost to each of a center of pressure that indicates an amount of force on the end component, a capture point that indicates a position on the surface based on a velocity of the body and a center of mass of the body, a forward acceleration of the body, and a lateral acceleration of the body; determining a new forward position and a new lateral position of the robotic device that reduces the height acceleration and the pitch acce