Abstract: Conventional laptop computers may utilize a door-hinge style or in a bezel-behind-base style hinge to connect a display with a keyboard of the laptop computer. Typically, these hinges present a discontinuous visual impression to the user. Presenting a more continuous visual impression of the hinge to the user suggests a higher overall quality of the computing device to the user and is thus desirable to the user. The disclosed virtual pivot hinge pivots about a pivot axis running between the display and the keyboard. The hardware of the hinge is located away from the pivot axis, which creates a virtual pivoting action about the axis that maintains a consistent front gap distance (or no front gap) between the display and the keyboard. The resulting visual impression to the user is that the display is floating above keyboard at the same or similar distance regardless of the display angle.

Abstract: A docking mechanism is described. The docking mechanism may include a locking protrusion and a locking receptacle configured to receive the locking protrusion and having an inclined surface. The docking mechanism may include a wedging member abutting the inclined surface. The docking mechanism may include a locking detent. The locking detent may have a spring configured to bias the locking detent towards the locking protrusion. Computing devices that include docking mechanisms are also described. Methods of use of the docking mechanisms are also described.

Abstract: A computing device is described. The computing device may include a first portion and a second portion separably connected to the first portion. A locking mechanism may be configured to lock the first portion to the second portion. The locking mechanism may include a locking receptacle connected to the first portion and a locking protrusion connected to the second portion. The locking receptacle may include a rotating lock and may have an aperture through which the locking protrusion is insertable. The computing device may include an actuator mechanically coupled to the locking mechanism and configured to unlock the first portion from the second portion.

Abstract: An apparatus for locking an electronic device includes an actuator, a return mechanism, and an arm. The actuator includes an actuator SMM wire that is configured to apply a contraction force. The return mechanism includes a return SMM wire that is configured to apply a return force opposite the contraction force. The arm is movable toward an unlocked position by the actuator and movable toward a locked position by the return force. The arm has at least one equilibrium position with less than 1 Newton of force on the arm from the actuator and less than 1 Newton of force on the arm from the return mechanism.

Abstract: A low-pressure hinge includes a plurality of segments with at least one upper frictional element and at least one lower frictional element where the at least one upper frictional element and the at least one lower frictional element are positioned on opposing sides of a segment of the plurality of segments. The hinge further includes a compression element that compresses the at least one upper frictional element and at least one lower frictional element against the segment with a compression force having a pressure less than 5,000 pounds per square inch.

Abstract: A docking mechanism is described. The docking mechanism may include a locking protrusion and a locking receptacle configured to receive the locking protrusion and having an inclined surface. The docking mechanism may include a wedging member abutting the inclined surface. The docking mechanism may include a locking detent. The locking detent may have a spring configured to bias the locking detent towards the locking protrusion. Computing devices that include docking mechanisms are also described. Methods of use of the docking mechanisms are also described.

Abstract: A computing device is described. The computing device may include a first portion and a second portion separably connected to the first portion. A locking mechanism may be configured to lock the first portion to the second portion. The locking mechanism may include a locking receptacle connected to the first portion and a locking protrusion connected to the second portion. The locking receptacle may include a rotating lock and may have an aperture through which the locking protrusion is insertable. The computing device may include an actuator mechanically coupled to the locking mechanism and configured to unlock the first portion from the second portion.

Abstract: A docking mechanism is described. The docking mechanism may include a locking protrusion and a locking receptacle configured to receive the locking protrusion and having an inclined surface. The docking mechanism may include a wedging member abutting the inclined surface. The docking mechanism may include a locking detent. The locking detent may have a spring configured to bias the locking detent towards the locking protrusion. Computing devices that include docking mechanisms are also described. Methods of use of the docking mechanisms are also described.

Abstract: A docking mechanism is described. The docking mechanism may include a locking protrusion and a locking receptacle configured to receive the locking protrusion and having an inclined surface. The docking mechanism may include a wedging member abutting the inclined surface. The docking mechanism may include a locking detent. The locking detent may have a spring configured to bias the locking detent towards the locking protrusion. Computing devices that include docking mechanisms are also described. Methods of use of the docking mechanisms are also described.

Abstract: A computing device may include a housing with an aperture. A switch with an activation surface is connected to the housing. A button may be slidable within the aperture and may be configured to receive an activation force from a user to activate the switch. The button may be moveable to activate the switch. The button may have a back surface that is offset from the activation surface of the switch such that when the button is moved to the active position the activation surface and the back surface do not come into direct contact. An adapter may be positioned between the switch and the button, where the adapter has a switch surface and a button surface. The button surface may be aligned with the back surface of the button and the switch surface may be aligned with the activation surface of the switch.

Abstract: A lock for actively locking an electronic device includes an engagement member that is movable by an actuator. The actuator moves the engagement member to the locked position with a first amount of power from the power source and from the locked position to an unlocked position with a second amount of power from the power source. The engagement member will passively remain in the unlocked position or the locked position.

Abstract: An apparatus for locking an electronic device includes an actuator, a return mechanism, and an arm. The actuator includes an actuator SMM wire that is configured to apply a contraction force. The return mechanism includes a return SMM wire that is configured to apply a return force opposite the contraction force. The arm is movable toward an unlocked position by the actuator and movable toward a locked position by the return force. The arm has at least one equilibrium position with less than 1 Newton of force on the arm from the actuator and less than 1 Newton of force on the arm from the return mechanism.

Abstract: In some embodiments, an apparatus for locking a computing device includes an actuator, a locking protrusion connected to a first portion of the computing device, a locking receptacle connected to a second portion of the computing device, a shape memory material (SMM) wire, and a force conditioner. The SMM wire has a first state and a second state and is movable between states by the actuator. The first state and the second state have first and second lengths, respectively. Moving from the first state to the second state applies a contraction force along a longitudinal direction of the SMM wire. The force conditioner is configured to apply a return force to the SMM wire that opposes the contraction face. The return force returns the SMM wire toward the first state while moving a maximum available force of the SMM wire to the second state of the SMM wire.

Abstract: A lock for actively locking an electronic device includes an engagement member that is movable by an actuator. The actuator moves the engagement member to the locked position with a first amount of power from the power source and from the locked position to an unlocked position with a second amount of power from the power source. The engagement member will passively remain in the unlocked position or the locked position.

Abstract: Devices, systems, and methods for locking a hybrid electronic device are described herein. An electronic device may include a housing, a first lock component attached to the housing or positioned in an opening of the housing, and a second lock component attached to the housing or positioned in an opening of the housing. The electronic device may be configured to connect with a locking device at the first lock component. The electronic device may also be configured to connect with an additional electronic device at the second lock component to provide a hybrid electronic device. Additionally, when the locking device is connected at the first lock component, the electronic device is configured to prevent the additional electronic device from being detached at the second lock component.

Abstract: A lock for actively locking an electronic device includes an engagement member that is movable by an actuator. The actuator moves the engagement member to the locked position with a first amount of power from the power source and from the locked position to an unlocked position with a second amount of power from the power source. The engagement member will passively remain in the unlocked position or the locked position.

Abstract: A computing device is described. The computing device may include a first portion and a second portion separably connected to the first portion. A locking mechanism may be configured to lock the first portion to the second portion. The locking mechanism may include a locking receptacle connected to the first portion and a locking protrusion connected to the second portion. The locking receptacle may include a rotating lock and may have an aperture through which the locking protrusion is insertable. The computing device may include an actuator mechanically coupled to the locking mechanism and configured to unlock the first portion from the second portion.

Abstract: A computing device is described. The computing device may include a first portion and a second portion separably connected to the first portion. A locking mechanism may be configured to lock the first portion to the second portion. The locking mechanism may include a locking receptacle connected to the first portion and a locking protrusion connected to the second portion. The locking receptacle may include a rotating lock and may have an aperture through which the locking protrusion is insertable. The computing device may include an actuator mechanically coupled to the locking mechanism and configured to unlock the first portion from the second portion.

Abstract: A computing device is described. The computing device includes a first portion with a protrusion and a second portion separably connected to the first portion. The second portion has a receptacle. An undocking assist mechanism is configured to separate the first portion from the second portion when the protrusion is at least partially inserted into the receptacle. An actuator is configured to actuate the undocking assist mechanism. Methods of use are also described.

Abstract: A computing device is described. The computing device may include a first portion and a second portion separably connected to the first portion. A locking mechanism may be configured to lock the first portion to the second portion. The locking mechanism may include a locking receptacle connected to the first portion and a locking protrusion connected to the second portion. The locking receptacle may include a rotating lock and may have an aperture through which the locking protrusion is insertable. The computing device may include an actuator mechanically coupled to the locking mechanism and configured to unlock the first portion from the second portion.