Abstract: A haptic device configured to provide haptic feedback to a user. In one aspect, a user or part of a user is located on the haptic device including actuators and damping elements. A haptic feedback wave is generated by an actuator and propagated to the user or part of the user on the haptic device. Damping elements receive the haptic feedback wave and suppress the haptic feedback wave to reduce a reflection thereof.

Abstract: A sheet jammer device comprises a first jamming sheet having a first surface within a compression region. A first inflatable bladder includes a first contact area within the compression region and a second jamming sheet has a surface within the compression. A second inflatable bladder that includes a second contact area that is within the compression region. An amount of inflation of the first inflatable bladder and the second inflatable bladder controls the first friction force and the second friction force to restrict movement of the first jamming sheet relative to the second jamming sheet.

Abstract: A method for large scale integration of haptic devices is described. The method comprises forming a first elastomer layer of a large scale integration (LSI) device on a substrate according to a specified manufacturing process, the first elastomer layer having a plurality of fluid based circuits, the first elastomer layer adhering to a plurality of formation specifications. The method further comprises curing the first elastomer layer. Additionally, one or more additional elastomer layers of the LSI device are formed with the first elastomer layer according to the specified manufacturing process, the one or more additional elastomer layers having a plurality of fluid based circuits, the one or more additional elastomer layers adhering to the plurality of formation specifications.

Abstract: An actuator configured to provide haptic feedback to a user. The actuator is located on a plate and is configured to apply various excitations to the plate to generate a mechanical wave propagating in the controlled direction. The excitations can be a translational motion of the actuator (or a portion of the actuator) in two or three perpendicular axes. Alternatively, the excitations can be a non-translational motion (e.g., rotation about an axis) of the actuator (or a portion of the actuator). By generating the mechanical wave traveling in the controlled direction, loss of energy due to scattering of the mechanical wave can be obviated.

Abstract: A virtual reality system enables a user to interact with virtual objects. The system includes a fiducial ring, an imaging device and a console. The fiducial ring includes a ring body that includes a plurality of fiducial markers that each correspond to a different location on the ring body. An imaging device is configured to capture one or more images of the fiducial ring. The console receives the images that include an image of one or more fiducial markers. Based on the received images of the fiducial markers, the console determines a location on the fiducial ring that corresponds to the imaged fiducial marker. The console determines a position of the fiducial ring based on the determined location of the fiducial marker on the fiducial ring. The console provides content to a head mounted display (HMD) based on the determined position of the fiducial ring.

Abstract: A haptic feedback glove worn by a user provides an amount of a resistance to a physical movement of a portion of the user's hand. The haptic feedback glove includes a glove body, an expandable bladder and a pressure source. The glove body includes a first portion corresponding to a first phalange of a user hand, a second portion corresponding to a second phalange of the user hand, and a third portion corresponding to a joint between the first phalange and the second phalange of the user hand. The expandable bladder is coupled to the third portion of the glove body. The expandable bladder has an adjustable size that controls an amount of relative movement between the first portion and the second portion of the glove body. The pressure source is coupled to the glove body, and is configured to adjust the size of the expandable bladder.

Abstract: A sensor records information about skin stretch perceived by a user based on an interaction with a real object. The sensor includes a mechanical housing configured to be worn on a finger of a user, and a mechanism coupled to the mechanical housing. The mechanism includes a first bearing that rotates in a first direction in response to an interaction with a surface. The mechanism also includes a second bearing coupled to the first bearing, such that rotation of the first bearing causes the second bearing to rotate in a direction opposite to the first direction. The second bearing is in contact with a portion of the finger, and includes a feedback surface that simulates a force associated with the interaction with the surface. The sensor includes a controller configured to monitor rotation of the second bearing and record skin stretch information responsive to the interaction with the surface.

Abstract: Disclosed is a force ground device (e.g., a glove) including one or more tendons coupled to actuators for providing haptic feedback when worn by a user. The force ground device includes a wristband that couples to the tendons or to the actuators. The wristband grounds forces from the compressed tendons to the wrist of the user. The wristband may include two force grounding segments adjacent to the ulnar and radial sides of the wrist. The wristband may also include a tension adjustment mechanism (e.g., a ratchet) to adjust the tension of the wristband.

Abstract: A haptic glove comprises a glove body including a glove digit corresponding to a phalange of a user hand. The glove digit has a first ribbon layer of a first average width and a second ribbon layer of a second average width greater than the first average width. The first and second ribbon layers are configured to be positioned on a first surface of the digit and formed lengthwise along a bend centerline of the glove digit that bisects a surface of the glove digit. A central axis of the second ribbon layer is aligned with a central axis of the first ribbon layer. The first ribbon layer comprises a first extendible material having a first range of elastic extensibility and the second ribbon layer comprises a second extendible material having a second range of elastic extensibility greater than the first range of elastic extensibility of the first ribbon layer.

Abstract: A haptic glove includes a glove body including a glove digit corresponding to a phalange of a user hand. The glove digit has a pair of flexible tendons, including a first and a second tendon, which are parallel to a bend centerline that bisects a surface of the glove digit. The first and second tendons are positioned respectively on opposite sides of the bend centerline. The haptic glove further comprises an actuator coupled to the glove body and the first and second tendons, the actuator configured to actuate the tendons to control movement of the glove digit.

Abstract: A haptic device configured to provide haptic feedback to a user. In one aspect, a user or part of a user is located on the haptic device including actuators and damping elements. A haptic feedback wave is generated by an actuator and propagated to the user or part of the user on the haptic device. Damping elements receive the haptic feedback wave and suppress the haptic feedback wave to reduce a reflection thereof.

Abstract: A strain measurement ring measures strain information describing deformation of a strain-sensitive element included in the strain measurement ring due to movement of a user's finger. The strain measurement ring includes a semi-rigid band coupled to a deformable band, which together encompass a portion of the user's body. The semi-rigid band includes two coupling ends each coupled to a respective coupling end of the deformable band. The deformable band includes the strain-sensitive element. The strain measurement ring may include an emitter to transmit strain information to a virtual reality/augmented reality (VR/AR) console. The strain measurement ring may include an actuator to change the tension of the deformable band in response to haptic command signals from a VR/AR console. As a result, the strain measurement ring may apply pressure to the user's skin to simulate contact with a virtual object.

Abstract: A haptic device configured to provide haptic feedback to a user. In one aspect, a user or part of a user is located on the haptic device including actuators and damping elements. A haptic feedback wave is generated by an actuator and propagated to the user or part of the user on the haptic device. Damping elements receive the haptic feedback wave and suppress the haptic feedback wave to reduce a reflection thereof.

Abstract: An actuator configured to provide haptic feedback to a user. The actuator is located on a plate and is configured to apply various excitations to the plate to generate a mechanical wave propagating in the controlled direction. The excitations can be a translational motion of the actuator (or a portion of the actuator) in two or three perpendicular axes. Alternatively, the excitations can be a non-translational motion (e.g., rotation about an axis) of the actuator (or a portion of the actuator). By generating the mechanical wave traveling in the controlled direction, loss of energy due to scattering of the mechanical wave can be obviated.

Abstract: A deformation sensing fabric comprises a fabric substrate comprising a first fabric layer and a first conductive element woven into the first fabric layer. The first conductive element outputs a first instrumented signal, responsive to an applied stimulus signal, indicative of a measure of change in an electrical property of the first conductive element in response to a strain applied to the fabric substrate along a long-axis of the first conductive element. The first conductive element is instrumented by a measurement system which stimulates the first conductive element and measures an electrical property of the first conductive element.

Abstract: An actuator configured to provide haptic feedback to a user. The actuator is located on a plate and is configured to apply various excitations to the plate to generate a mechanical wave propagating in the controlled direction. The excitations can be a translational motion of the actuator (or a portion of the actuator) in two or three perpendicular axes. Alternatively, the excitations can be a non-translational motion (e.g., rotation about an axis) of the actuator (or a portion of the actuator). By generating the mechanical wave traveling in the controlled direction, loss of energy due to scattering of the mechanical wave can be obviated.

Abstract: A sensor records information about skin stretch perceived by a user based on an interaction with a real object. The sensor includes a mechanical housing configured to be worn on a finger of a user, and a mechanism coupled to the mechanical housing. The mechanism includes a first bearing that rotates in a first direction in response to an interaction with a surface. The mechanism also includes a second bearing coupled to the first bearing, such that rotation of the first bearing causes the second bearing to rotate in a direction opposite to the first direction. The second bearing is in contact with a portion of the finger, and includes a feedback surface that simulates a force associated with the interaction with the surface. The sensor includes a controller configured to monitor rotation of the second bearing and record skin stretch information responsive to the interaction with the surface.

Abstract: A virtual reality (VR) headset includes an electronic display element that outputs image light via a plurality of sub-pixels that are separated from each other by a dark space. To mask the dark space between adjacent sub-pixels in the electronic display element, an optics block (e.g., a lens) in the VR headset oscillates or the electronic display element oscillates. For example, a piezoelectric material is coupled to the electronic display element or to the optics block. When a voltage is applied to the piezoelectric material, vibration of the piezoelectric material causes oscillation of the electronic display element or the optics block. The oscillation generates blur spots in the image light that mask the dark space between adjacent sub-pixels, with each blur spot corresponding to a blurred image of a sub-pixel in the image light.

Abstract: An input interface configured to be worn on a portion of a user's body includes tendons coupled to various sections of the glove. A tendon includes one or more activation mechanisms that, when activated, prevent or restrict a particular range of motion. Additionally, a tendon may be coupled to a plate that is coupled to one or more additional tendon, so when an activation mechanism included in the tendon is activated, the one or more additional tendons coupled to the plate that are also coupled to the tendon move, stiffening the additional tendons as well as the tendon.

Abstract: A deformation sensing fabric comprises a fabric substrate comprising a first fabric layer and a first conductive element woven into the first fabric layer. The first conductive element outputs a first instrumented signal, responsive to an applied stimulus signal, indicative of a measure of change in an electrical property of the first conductive element in response to a strain applied to the fabric substrate along a long-axis of the first conductive element. The first conductive element is instrumented by a measurement system which stimulates the first conductive element and measures an electrical property of the first conductive element.