Abstract: A macro-mini actuation mechanism for pneumatic pouches is provided which involves stacking smaller proximal pouches (proximal layer) underneath larger distal pouches (distal layer). The proximal layer of smaller pouches is the contact area with e.g. a (human) body. Macro-mini pneumatic actuation of pouches for wearable haptic displays allows for the control of contact area of pneumatic pouches and the ability to cover large areas while maintaining a fast-dynamic response and higher spatial resolutions. This stacked pouch concept allows for pressure/force feedback to a user—something which cannot be rendered by vibrotactile actuators alone. Control of effective pouch height may also allow a potential wearable haptic display to better conform to the human body. A pressure-based display with stacked pouches could allow for larger tolerances between the display and the human body without sacrificing contact area, allowing better fit across users.

Abstract: Technology is provided for controlling the motion of soft growing robots during retraction to prevent uncontrollable buckling or bending. A double walled flexible tubular robot is provided with an inside wall, an outside wall, and a folded tip. A retraction device located at the folded tip has a routing aperture sized to encompass the inside wall and for routing the inside wall through the retraction device. The retraction device further has a retraction mechanism inside the retraction device to controllably retract material of the inside wall through the routing aperture in the direction away from the folded tip, thereby decreasing the outside wall, creating more inside wall, and as such shortening the length of the flexible robot.

Abstract: A macro-mini actuation mechanism for pneumatic pouches is provided which involves stacking smaller proximal pouches (proximal layer) underneath larger distal pouches (distal layer). The proximal layer of smaller pouches is the contact area with e.g. a (human) body. Macro-mini pneumatic actuation of pouches for wearable haptic displays allows for the control of contact area of pneumatic pouches and the ability to cover large areas while maintaining a fast-dynamic response and higher spatial resolutions. This stacked pouch concept allows for pressure/force feedback to a user—something which cannot be rendered by vibrotactile actuators alone. Control of effective pouch height may also allow a potential wearable haptic display to better conform to the human body. A pressure-based display with stacked pouches could allow for larger tolerances between the display and the human body without sacrificing contact area, allowing better fit across users.

Abstract: A robot for navigating an environment through growth is provided. The growing robot has a thin-walled, hollow, pressurized, compliant body that elongates the body by everting from its tip new wall material that is stored inside the body. The robot controls the shape of the body by actively controlling the relative lengths of the wall material along opposing sides of the body allowing steering.

Abstract: A robot for navigating an environment through growth is provided. The growing robot has a thin-walled, hollow, pressurized, compliant body that elongates the body by everting from its tip new wall material that is stored inside the body. The robot controls the shape of the body by actively controlling the relative lengths of the wall material along opposing sides of the body allowing steering.