Systems and methods for clearing a top drive from an operational area of the mast such that operations may be performed along the rail without interference from the top drive. Systems and methods of the present disclosure provide for arranging the top drive in a parked configuration outside of, or generally behind, the mast. A guide rail may be arranged within an operational area of a mast and may have a pair of interchangeable rail sections, each of which may be configured for arrangement in either an operating configuration, where the rail section may be positioned within the operational area of the mast to form part of the rail, or a parked configuration, where the rail section may be positioned outside of the operational area. Each interchangeable rail section may be pivotable about an axis and may be arranged on a pivotable gate of the mast.

Methods, systems, and apparatus, including computer programs encoded on computer storage media, for logging real-time data of a robot control system. One of the systems comprises a real-time robotic control system comprising one or more computers, programmed to perform operations comprising i) software module loops and ii) real-time data logging, wherein each software module loop comprises a plurality of software modules executed repeatedly in a predetermined sequence, each software module executes within a predetermined time window, and the real-time data logging comprises copying segments of real-time data used by a particular software module to a buffer accessible by a non-real-time downstream system, wherein each segment of real-time data is copied at a respective predetermined time relative to execution of the software modules in the software module loop; and the non-real-time downstream system comprising one or more computers, the non-real-time downstream system programmed to perform operations that consume the real-time messages.

An example method may include i) detecting a disturbance to a gait of a robot, where the gait includes a swing state and a step down state, the swing state including a target swing trajectory for a foot of the robot, and where the target swing trajectory includes a beginning and an end; and ii) based on the detected disturbance, causing the foot of the robot to enter the step down state before the foot reaches the end of the target swing trajectory.

A mobile robot is provided to follow a trajectory and adopt a behavior which can be defined by movements of articulated limbs of the robot. The mobile robot is equipped with a processor which is configured, based on instructions defining a motion of the mobile robot and instructions defining a behavior of the mobile robot, to calculate a target trajectory of a center of mass of the mobile robot; calculate, based on the target trajectory of the center of mass of the mobile robot and dynamic constraints of the mobile robot, a predicted trajectory of the center of mass of the mobile robot over a time horizon, and calculate, based on the predicted trajectory of the center of mass of the mobile robot and the instructions defining a behavior of the mobile robot, predicted movements of articulated limbs.

An intuitive control system for lifting equipment is described. The intuitive control system translates user defined inputs into machine expressions of movement that are in turn used to control a construction lift or similar piece of construction equipment. Orientation and relative position sensors may be incorporated into the translation and control system for correct user control of the lifting equipment in various operating conditions.

Apparatus and methods for carpet drift estimation are disclosed. In certain implementations, a robotic device includes an actuator system to move the body across a surface. A first set of sensors can sense an actuation characteristic of the actuator system. For example, the first set of sensors can include odometry sensors for sensing wheel rotations of the actuator system. A second set of sensors can sense a motion characteristic of the body. The first set of sensors may be a different type of sensor than the second set of sensors. A controller can estimate carpet drift based at least on the actuation characteristic sensed by the first set of sensors and the motion characteristic sensed by the second set of sensors.

A remote control robot system includes a slave arm, a master main body imitating the shape of an object handled by the slave arm, a manipulation receiving device configured to receive manipulation of an operator based on the position and posture of the master main body, and a control device configured to control operation of the slave arm based on the manipulation received by the manipulation receiving device so that behavior of the object corresponds to behavior of the master main body.

A remote-control manipulator system includes a manipulator configured to receive a manipulating instruction from an operator, a slave arm configured to perform a series of works comprised of a plurality of processes, a camera configured to image operation of the slave arm, a display device configured to display an image captured by the camera, a storage device configured to store information related to environment in a workspace as an environment model, and a control device. The control device is configured, while operating the slave arm manually or hybridly, to acquire circumference information that is information related to a circumference area of an area imaged by the camera based on the environment model stored in the storage device, and display on the display device so that the image captured by the camera and the circumference information are interlocked.

A system and method of assisting operator engagement with input devices includes a repositionable structure configured to support a physical input device, a hand detection system, and a control unit. The repositionable structure includes one or more actuators. The physical input device is configured to be operated by a hand of an operator. The control unit is configured to detect the hand of the operator using the hand detection system and in response to a trigger condition, command the one or more actuators to move the input device from a first orientation to a second orientation, wherein the second orientation is closer to a grasping orientation of the hand than the first orientation is to the grasping orientation of the hand.

A method is provided for grasping randomly sized and randomly located objects. The method may include assigning a score associated with the likelihood of successfully grasping an object. Other features of the method may include orientation of the end effector, a reachability check, and crash recovery.