A flexure device comprising an interior flexure member having first and second interior flexible blades each formed with an interior end portion and separate interior body portions. An exterior flexure member can have first and second exterior flexible blades each formed with separate exterior end portions and an exterior body portion. The first interior end portion and the first exterior end portion form a first flexure end portion, the second interior portion and the second exterior portion form a second flexure end portion. The interior and exterior body portions are coupled to form a flexure body portion, such that the first interior and exterior flexible blades form a first flexure that facilitates rotation between the first flexure end portion and the flexure body portion. The second interior and exterior flexible blades form a second flexure that facilitates rotation between the second flexure end portion and the flexure body portion.

A multi-axis flexure device can include a first support base, a second support base, and a central coupler. The multi-axis flexure device can also include a first flexure device rotatably coupling the first support base and the central coupler to one another to facilitate rotation about a first axis, and a second flexure device rotatably coupling the second support base and the central coupler to one another to facilitate rotation about a second axis. Each flexure device can include a first flexure, a second flexure, and a flexure coupler coupled to the first and second flexures. The first flexure and the second flexure of the first flexure device can, respectively, be coupled to the first support base and the central coupler. The first flexure and the second flexure of the second flexure device can, respectively, be coupled to the second support base and the central coupler.

A wearable device includes a frame, two feet, and two pivoting modules. Each of the pivoting modules includes a first bracket fixedly connected to the frame, and a second bracket fixedly connected to one of the feet and pivotally coupled to the first bracket. The second bracket includes a positioning member and an inserting member. The positioning member is located in the first bracket, and the positioning member includes a plurality of slots. The inserting member is switchably inserted into one of the slots for adjusting a maximum outreaching volume from the frame to the feet.

A camera module includes a housing, a carrier, a frame, a lens holder, an autofocusing (AF) ball bearing, and an optical image stabilization (OIS) ball bearing. The carrier is coupled to the housing and configured to move in an optical axis direction. The frame is coupled to the carrier and configured to move in a first axis direction, perpendicular to the optical axis direction. The lens holder is coupled to the frame and configured to move in a second axis direction, perpendicular to the optical axis and the first axis. The AF ball bearing is disposed between the housing and the carrier. The OIS ball bearing is disposed on either one or both of the carrier and the frame, and the frame and the lens holder. Either one or both of the AF ball bearing and the OIS ball bearing have an elastic modulus of 20 GPa or less.

An isolation joint with an integral angle measurement system. The isolation joint includes a suspension interface yoke, a payload support member, a spherical bearing, and an integral angle measurement system. The suspension interface yoke includes a suspension interface configured to couple the suspension interface yoke to one or more suspension bars. The payload support member includes a payload interface configured to couple a payload to the payload support member. The spherical bearing includes an inner race secured to one of the suspension interface yoke and the payload support member and an outer race secured to the other of the suspension interface yoke and the payload support member. The integral angle measurement system includes a plurality of position sensors configured to measure a change in position between the suspension interface yoke and the payload support member.

A flexure bearing includes an inner race, an outer race, and a plurality of substantially planar radially extending blades coupled between the inner and outer race. The blades have a thickness that is thinner than a thickness of the inner and outer races. The inner race, outer race, and blades have substantially the same height. At least one heating element is coupled to the inner race and/or the outer race. The heating element is configured to apply heat to the race that it is coupled to in order to tune the flexure bearing.

Kinematic mounts disclosed in this application are made from three main components: a housing, a footing, and a tightening mechanism. The tightening mechanism includes three parts: a top portion, a bottom portion, and a locking interface mechanism. When the top portion, which includes a hollow tip with interior threading, is screwed down onto the bottom portion, which includes a threaded tip, the locking interface component is pressed against at least one interior surface of the housing that causes the housing to be pressed against the footing. This action holds the housing in place relative to the footing while simultaneously preventing unwanted movement of the housing during tightening.

The present disclosure relates to a cross-pivot flexure system. In one embodiment the system may incorporate a center post element having a first head at a first end thereof, and a second head at a second end thereof. The first head may be arranged along a first longitudinal axis and the second head may be arranged along a second longitudinal axis. The first head may be attached to an immovable ground element through at least one first cross-pivot element for enabling rotational movement about the first longitudinal axis, while the second head may be attached to a motion stage flexure via at least one second cross-pivot element. This construction permits rotational movement of the second head about the second rotational axis. The first and second longitudinal axes are further arranged so that they intersect one another.

An isolation joint with an integral angle measurement system. The isolation joint includes a suspension interface yoke, a payload support member, a spherical bearing, and an integral angle measurement system. The suspension interface yoke includes a suspension interface configured to couple the suspension interface yoke to one or more suspension bars. The payload support member includes a payload interface configured to couple a payload to the payload support member. The spherical bearing includes an inner race secured to one of the suspension interface yoke and the payload support member and an outer race secured to the other of the suspension interface yoke and the payload support member. The integral angle measurement system includes a plurality of position sensors configured to measure a change in position between the suspension interface yoke and the payload support member.

A joint for coupling a side arm to a frame of a pair of glasses. The joint includes a post, a plurality of prongs, and optionally a nut. The post is configured to be secured to one of the side arm or the frame and the plurality of prongs are configured to be secured to the other of the side arm or the frame. The post includes a shaft and an enlarged head at a distal end of the shaft. The plurality of prongs define a socket configured to receive at least a portion of the enlarged head of the post and apply a compressive force against the enlarged head of the post. The nut may be configured to generate a compressive force against the plurality of prongs. The compressive force may be adjusted by threading the nut along the length of the prongs. The nut may threadably engage a base that the prongs extend from and/or the prongs.