Abstract: A joint supporting wireless communication includes a first structure having an attached first wireless transceiver and a second structure having an attached second wireless transceiver. The first and second structures are arranged to maintain electrical contact during rotation or other movements. In some embodiments, the first and second wireless transceivers can be RF transceivers or optical transceivers. In some embodiments, the first and second structures define at least a part of a mobile humanoid robot.

Abstract: A system in accordance with at least some embodiments of the present technology includes a robot and a dock. The robot includes a body and a plurality of legs connected to the body through which the robot is configured to ambulate. The robot further includes a hanger carried by the body and a charge-receiving electrode at the hanger. The dock includes a hook, a charge-dispensing electrode at the hook, and a guide that urges the hanger into alignment with the hook. The system is transitionable between an undocked state and a docked state. In the undocked state, the robot and the dock are spaced apart from one another. In the docked state, the hanger is received at the hook, the dock supports at least a portion of a weight of the robot via the hook, and the charge-receiving electrode is electrically connected to the charge-dispensing electrode.

Abstract: A method in accordance with at least some embodiments of the present technology includes generating a first motion command for changing a pose of a mobile robot. This occurs via a computer system operably associated with the mobile robot. The method further includes determining an indication of a fault-state fall property of the mobile robot corresponding to the first motion command. The indication is based at least partially on joint-encoder data and inclinometer data from the mobile robot. The method still further includes generating a second motion command for changing the pose of the mobile robot based at least partially on the indication. The method also includes executing movement of the mobile robot corresponding to the second motion command. Executing this movement occurs via an actuator of the mobile robot and causes the fault-state fall property to move toward a target range.

Abstract: A system in accordance with at least some embodiments of the present technology includes a robot and a dock. The robot includes a body and a plurality of legs connected to the body through which the robot is configured to ambulate. The robot further includes a hanger carried by the body and a charge-receiving electrode at the hanger. The dock includes a hook, a charge-dispensing electrode at the hook, and a guide that urges the hanger into alignment with the hook. The system is transitionable between an undocked state and a docked state. In the undocked state, the robot and the dock are spaced apart from one another. In the docked state, the hanger is received at the hook, the dock supports at least a portion of a weight of the robot via the hook, and the charge-receiving electrode is electrically connected to the charge-dispensing electrode.

Abstract: A method in accordance with at least some embodiments of the present technology includes determining first hazard information about a human in an environment at a first time. The method further includes decelerating a mobile robot in the environment based at least partially on the first hazard information. The method further includes determining second hazard information about the human at a second time after the first time. The method further includes reconfiguring the mobile robot based at least partially on the second hazard information. Reconfiguring the mobile robot includes moving the mobile robot from a standing configuration to a non-standing configuration. The method further includes determining third hazard information about the human at a third time after the second time. Finally, the method includes causing a safe operating stop of the mobile robot based at least partially on the third hazard information.

Abstract: A method in accordance with at least some embodiments of the present technology includes determining first hazard information about a human in an environment at a first time. The method further includes decelerating a mobile robot in the environment based at least partially on the first hazard information. The method further includes determining second hazard information about the human at a second time after the first time. The method further includes reconfiguring the mobile robot based at least partially on the second hazard information. Reconfiguring the mobile robot includes moving the mobile robot from a standing configuration to a non-standing configuration. The method further includes determining third hazard information about the human at a third time after the second time. Finally, the method includes causing a safe operating stop of the mobile robot based at least partially on the third hazard information.

Abstract: A method in accordance with at least some embodiments of the present technology includes determining first hazard information about a human in an environment at a first time. The method further includes decelerating a mobile robot in the environment based at least partially on the first hazard information. The method further includes determining second hazard information about the human at a second time after the first time. The method further includes reconfiguring the mobile robot based at least partially on the second hazard information. Reconfiguring the mobile robot includes moving the mobile robot from a standing configuration to a non-standing configuration. The method further includes determining third hazard information about the human at a third time after the second time. Finally, the method includes causing a safe operating stop of the mobile robot based at least partially on the third hazard information.

Abstract: A transmission includes a housing having a first end and a second end opposite the first end, a carrier mounted to the housing, an input shaft, an output shaft, a passage that extends from the housings first end to the housings second end to allow a via through the housing, an input sensor, and an output sensor. The carrier has a first side that faces in a first direction, and a second side that faces in a direction other than the first direction. The input sensor is mounted to the carrier and disposed on the first side of the carrier. The output sensor is mounted to the same carrier and disposed on the carrier's second side. The input and output shafts rotate about the same axis.

Abstract: A transmission includes a housing having a first end and a second end opposite the first end, a carrier mounted to the housing, an input shaft, an output shaft, a passage that extends from the housings first end to the housings second end to allow a via through the housing, an input sensor, and an output sensor. The carrier has a first side that faces in a first direction, and a second side that faces in a direction other than the first direction. The input sensor is mounted to the carrier and disposed on the first side of the carrier. The output sensor is mounted to the same carrier and disposed on the carrier's second side. The input and output shafts rotate about the same axis.