Abstract: An apparatus and method for damping haptic vibrations. A haptic output device is positioned within a device housing. The haptic output device has a haptic actuator and a haptic mass, the haptic mass being movable relative to the housing. A damper is positioned within the device housing. A controller is programmed to generate and deliver a haptic signal to the haptic actuator at a first time, and to generate and deliver a damping signal to the damper at a second time, the second time occurring after the first time. The method comprises moving a haptic mass, the haptic mass position in a housing; vibrating the housing in response to moving the haptic mass; damping movement of the haptic mass after a period of time; and substantially eliminating vibration of the housing in response to damping movement of the haptic mass.

Abstract: An actuator system configured to generate a haptic effect is provided. The actuator system includes a cavity configured to store an incompressible fluid, the cavity being disposed within a first substrate, a piezoelectric actuator disposed within a second substrate, and a diaphragm disposed between the cavity of the first substrate and the piezoelectric actuator of the second substrate.

Abstract: A flexible haptic actuator and corresponding method. The flexible haptic actuator comprises a core formed with a flexible material. The core defines a volume and is bendable. An electrical conductor is coiled around the core and is bendable. A casing surrounds the electrical conductor and at least a part of the core. The casing includes a plurality of flexible sections and a plurality of stiff sections. The casing is bendable. A haptic mass is suspended in the volume, the haptic mass being at least partially formed with a magnetic material. The haptic mass is movable in the volume in response to the electrical conductor generating a magnetic field.

Abstract: Devices and methods for providing localized haptic effects are provided. The devices include a haptically enabled display device having one or more haptic actuators. The one or more haptic actuators are located in a non-viewing area of a display screen of a haptically enabled display device and cause localized haptic effects in a viewing area of the display screen. The haptically enabled display device includes a processor configured to determine haptic control signals for activating the haptic actuators. The haptic control signal activates the one or more haptic actuators to provide a localized haptic effect at a target location in the viewing area, remote from the non-viewing area location of the one or more haptic actuators.

Abstract: One illustrative system disclosed herein includes a processor configured to determine a haptic effect and transmit a haptic signal associated with the haptic effect. The illustrative system also includes a multifunction haptic output device configured to receive the haptic signal and output the haptic effect. The multifunction haptic output device includes a single haptic actuator.

Abstract: Devices and methods for providing localized haptic effects are provided. The devices include a haptically enabled display device having one or more haptic actuators. The one or more haptic actuators are located in a non-viewing area of a display screen of a haptically enabled display device and cause localized haptic effects in a viewing area of the display screen. The haptically enabled display device includes a processor configured to determine haptic control signals for activating the haptic actuators. The haptic control signal activates the one or more haptic actuators to provide a localized haptic effect at a target location in the viewing area, remote from the non-viewing area location of the one or more haptic actuators.

Abstract: The present application relates generally to haptic actuators. For example, the application is directed to high performance parallel plate actuators, and more particularly an actuator that can be used to provide haptic feedback in a variety applications such as buttons, panels, track pads, touch panels, wearables, gaming devices and/or touch-sensitive surfaces.

Abstract: One illustrative system disclosed herein includes an enclosure configured to define a boundary of a chamber, the chamber including a material, and a flexible layer coupled overtop of the chamber and configured to enclose the chamber. The illustrative system also includes a first actuation device configured to receive a first haptic signal and responsively output a first haptic effect by changing a characteristic of the material to deform the flexible layer. The illustrative system also includes a second actuation device configured to receive a second haptic signal and responsively output a second haptic effect by applying an electrical signal to the flexible layer. The illustrative system further includes a processor in communication with the first actuation device and the second actuation device. The processor is configured to transmit the first haptic signal to the first actuation device and the second haptic signal to the second actuation device.

Abstract: This disclosure relates to fiber actuators for providing haptic feedback, and haptic actuation resulting from mechanical and/or electrostatic (non-mechanical) interactions with the fiber actuators. Such fiber actuators are useful in structural materials, including as elements of wearables or accessories.

Abstract: This disclosure relates to a smart material for providing haptic feedback, as well as haptic actuators, and suitably haptic actuation resulting from electroactive materials. Such haptic actuators are useful in structural materials, including as elements of wearables or accessories.

Abstract: Systems, devices, and methods for wirelessly delivering haptic effects are provided. The devices may include haptic actuators secured to various substrates, including the body and clothing of a user. The haptic actuators may be secured via adhesive and/or may be applied as a curable liquid. The haptic actuators may include an actuator element and a power element. The power element may include an antenna for receiving wireless power and control signals that may be transferred to the haptic actuator to cause a haptic effect.

Abstract: A system includes an electronic device that includes a display screen, a cover configured to cover the display screen, a sensor configured to sense an input gesture comprising deformation and/or movement of the cover relative to the electronic device, and a processor configured to determine an action for the electronic device to perform based on the input gesture, to determine a haptic effect to generate based on the input gesture and/or the action for the electronic device to perform, and to initiate the action. The system also includes a haptic output device configured to generate the haptic effect.

Abstract: Systems, devices, methods, non-transitory computer readable mediums for generating one or more haptic effects are provided. For example, a device includes a substrate including a plurality of haptic regions, and a plurality of haptic output devices, each haptic output device being coupled to a respective haptic region, and each haptic output device being configured to generate a haptic effect in response to receiving a haptic drive signal, as described herein. The haptic effect is perceptible to a user within one cycle of the haptic drive signal.

Abstract: A haptic system and a method of manufacturing a haptic system are provided. The haptic system includes a substrate and a haptic actuator. The substrate includes a region having a residual stress. The haptic actuator is associated with the substrate on or near the region and is configured to generate a haptic effect in response to receiving a haptic effect signal. The haptic effect generated by the haptic actuator is amplified by the residual stress associated with the region. The method of manufacturing the haptic system includes deforming an substrate into a deformed shape, applying an epoxy to the substrate, affixing a haptic actuator to the epoxy and curing the epoxy while holding the substrate in the deformed shape, and, after curing, releasing the substrate to create the region having the residual stress.

Abstract: A wearable device for providing haptic effects includes an open ring component configured to abut against to a first portion of a wearer. The open ring component has a C-shaped body with a first end, a second end spaced from and opposed to the first end, and a circumferential opening with a first width when the open ring component is in a non-actuated state. The open ring component includes a first laminate layer, a second laminate layer, and a macro-fiber composite actuator integrally formed with the first laminate layer and the second laminate layer. The macro-fiber composite actuator is configured to receive a command signal from a processor and deform to an actuated state in which the circumferential opening has a second width in response to the command signal to provide a force onto a second portion of the wearer that extends between the first end and the second end of the open ring component.

Abstract: A haptic output device includes a substrate, an array of electrodes disposed on the substrate, and a layer of dielectric material disposed on the array of electrodes. The layer of dielectric material has an exposed outer surface comprising a micro-patterned texture configured to increase adhesion between the exposed outer surface and a contact surface in contact with the exposed outer surface. The haptic output device includes a controller configured to direct a voltage potential across the array of electrodes to generate an electrostatic adhesive force between the exposed outer surface and the contact surface as a haptic effect.

Abstract: A haptic-enabled user interface device comprising a user input component, an elastomer suspension, a signal generating circuit, a signal sensing circuit, one or more switches, and a control unit is presented. The elastomer suspension is formed by at least one stack that includes an elastomeric layer, wherein the at least one stack forms at least one capacitor. The control unit is configured, in an actuation mode, to cause the one or more switches to electrically connect the signal generating circuit to the at least one capacitor and to electrically disconnect the signal sensing circuit from at least one capacitor, and to cause the signal generating circuit to apply a drive signal to the at least one capacitor. The control unit is further configured, in a sensing mode, to cause the one or more switches to electrically connect the signal sensing circuit to the at least one capacitor.

Abstract: This disclosure relates to haptic feedback generators, including bistable materials for providing haptic feedback to a user. Such haptic feedback generators are useful in structural materials, such as elements of wearables or accessories.

Abstract: A haptic actuator comprising a base and a haptic transducer at least partially suspended by the base. The haptic transducer comprises a substrate and a smart material operably connected to the substrate. The smart material has resonance in response to an electrical signal having a determined frequency, and the resonance causes the haptic transducer to vibrate and deliver a haptic effect.

Abstract: A haptic output device is configured to generate a deformation-based haptic effect and a vibration-based haptic effect. The haptic output device includes a shape memory material configured to change a shape thereof when heated and generate the deformation-based haptic effect, and a cooling device configured to cool the shape memory material and generate the vibration-based haptic effect.