Achieving a target gait in a legged robot based on steering commands

What is claimed is: 1. A method comprising: receiving, at at least one processor, a target gait for a legged robot having at least one articulated leg, the target gait based on input steering commands; based on the target gait, obtaining, at the at least one processor, a list of gait controllers, each gait controller defining a respective gait of the legged robot and including a respective validity test and steering commands for the respective gait; applying, by the at least one processor, a cost function to the gait controllers in the list, the cost function assigning respective costs to each gait controller; ordering, by the at least one processor, the list of gait controllers in increasing magnitude of the cost function; traversing, by the at least one processor, the ordered list in order until a validity test associated with a particular gait controller passes; and causing, by the at least one processor, actuation of the at least one articulated leg of the legged robot according to output parameters of the particular gait controller. 2. The method of claim 1 , wherein a cost for a given gait controller is based on: a difference between the steering commands of the given gait controller and the input steering commands; and a proximity of the legged robot to one or more obstacles when the legged robot operates according a given gait of the given gait controller for a pre-defined period of time. 3. The method of claim 2 , wherein the input steering commands comprise an input velocity and an input yaw rate, wherein the respective steering commands of the gait controllers comprise respective velocities and yaw rates, and wherein the difference between the steering commands of the given gait controller and the input steering commands is based on: a difference between the respective velocity of the given gait controller and the input velocity; and a difference between the respective yaw rate of the given gait controller and the input yaw rate. 4. The method of claim 3 , wherein the respective cost assigned to each gait controller increases: with the difference between the respective yaw rate of the given gait controller and the input yaw rate; or with the difference between the respective velocity of the given gait controller and the input velocity. 5. The method of claim 3 , wherein applying the cost function to the gait controllers in the list comprises: estimating a first location for the legged robot based on a first assumption that the legged robot operates according to the input velocity and input yaw rate for the pre-defined period of time; and estimating a second location for the legged robot based on a second assumption that the legged robot operates according to the given gait controller for the pre-defined period of time, wherein the cost is also based on a difference between the first location and the second location. 6. The method of claim 3 , wherein applying the cost function to the gait controllers in the list comprises: estimating a first yaw for the legged robot based on a first assumption that the legged robot operate according to the input yaw rate for the pre-defined period of time; and estimating a second yaw for the legged robot based on a second assumption that the legged robot operate according to the given gait controller for the pre-defined period of time, wherein the cost is also based on a difference between the first yaw and the second yaw. 7. The method of claim 2 , wherein the respective cost assigned to each gait controller increases in proportion to the proximity of the legged robot to the one or more obstacles when the robot operates according the given gait of the given gait controller for the pre-defined period of time. 8. The method of claim 2 , wherein the legged robot comprises a proximity sensor configured to detect obstacles in multiple directions, and wherein the proximity of the legged robot to the one or more obstacles is based on a signed-distance grid, points thereon representing respective distances from obstacles, and wherein the signed-distance grid is based on readings from the proximity sensor. 9. The method of claim 1 , wherein the gait controller of the target gait is at the beginning of the ordered list. 10. The method of claim 1 , wherein at least some of the gait controllers are either cyclic gait controllers that define respective touchdown timings and positions for feet of the legged robot that cause the legged robot to operate according to the respective gaits, acyclic gait controllers that define touchdown timings and positions for the feet that cause the legged robot to transition from one gait to another, or recovery gait controllers that define touchdown timings and positions for the feet that cause the legged robot to recover from deviations from a cyclic or acyclic gait. 11. A legged robot comprising: at least one articulated leg; at least one processor in communication with the at least one articulated leg; and a data storage device in communication with the at least one processor, the data storage device storing instructions that when executed on the at least one processor cause the at least one processor to perform operations comprising: receiving a target gait for the legged robot, the target gait based on input steering commands; based on the target gait, obtaining a list of gait controllers, each gait controller defining a respective gait of the legged robot and including a respective validity test and steering commands for the respective gait; applying a cost function to the gait controllers in the list, the cost function assigning respective costs to each gait controller; ordering the list of gait controllers in increasing magnitude of the cost function; traversing the ordered list in order until a validity test associated with a particular gait controller passes; and causing actuation of the at least one articulated leg of the legged robot according to output parameters of the particular gait controller. 12. The legged robot of claim 11 , wherein a cost for a given gait controller is based on: a difference between the steering commands of the given gait controller and the input steering commands; and a proximity of the legged robot to one or more obstacles when the legged robot operates according a given gait of the given gait controller for a pre-defined period of time. 13. The legged robot of claim 12 , wherein the input steering commands comprise an input velocity and an input yaw rate, wherein the respective steering commands of the gait controllers comprise respective velocities and yaw rates, and wherein the difference between the steering commands of the given gait controller and the input steering commands is based on: a difference between the respective velocity of the given gait controller and the input velocity; and a difference between the respective yaw rate of the given gait controller and the input yaw rate. 14. The legged robot of claim 13 , wherein the respective cost assigned to each gait controller increases: with the difference between the respective yaw rate of the given gait controller and the input yaw rate; or with the difference between the respective velocity of the given gait controller and the input velocity. 15. The legged robot of claim 13 , wherein applying the cost function to the gait controllers in the list comprises: estimating a first location for the legged robot based on a first assumption that the legged robot operates according to the input velocity and input yaw rate for the pre-defined period of time; and estimating a second location for the legged robot ba