Abstract: Embodiments of the present invention are directed toward electronic devices configured to produce haptic effects, and to haptic enabled film overlays for pressure sensitive surfaces. The systems and methods for haptic enabled film overlays include a processor and a plurality of sensors, a pressure sensitive touch surface coupled to the plurality of sensors and configured to detect a user interaction, and an overlay including a tactile user interface and a plurality of haptic output devices, the overlay being configured to provide a haptic effect in response to the user interaction.

Abstract: A method and apparatus of actuator control mechanisms for haptic effects are disclosed. The apparatus can include an actuator and a controller for controlling a haptic cell. Depending on the type of haptic effect desired, as well as the damping characteristics of the system, the controller can generate a kick-in pulse followed by a main pulse to create an increased acceleration response, and/or a breaking pulse to provide a damping effect for a short mechanical type of haptic effect.

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: A haptic actuator having a housing, a moveable mass, and first, second, and third electromagnets is disclosed. The first electromagnet is fixed to the housing. The moveable mass is suspended in the housing and at least partially surrounding the first electromagnet. The moveable mass has ferromagnetic material at a first end of the moveable mass, and ferromagnetic material at a second end opposite the first end. It further has a plurality of permanent magnets that are configured to magnetize the ferromagnetic material, such that when a current is applied to the first electromagnet, the ferromagnetic material of one of the first and second ends is attracted to the first electromagnet, and the ferromagnetic material of the other of the first and second ends is repelled. The second electromagnet and the third electromagnet are each fixed to the housing, and face opposite ends of the moveable mass.

Abstract: One illustrative system disclosed herein includes a computing device in communication with a sensor configured to detect a display device near the sensor, the computing device, or within a field of view of a user of the computing device. The sensor can also be configured to transmit a signal associated with the display device to a processor in communication with the sensor. The processor is configured to determine an availability of the display device to display or output content (e.g., texts, images, sounds, videos, etc.) and a location of the display device based on the signal. The processor is also configured to determine a haptic effect based on the availability and the location of the display device and transmit a haptic signal associated with the haptic effect. The illustrative system also includes a haptic output device configured to receive the haptic signal and output the haptic effect.

Abstract: One illustrative system disclosed herein includes a computing device with an electrostatic force (“ESF”) haptic output device coupled to a surface of the computing device. The ESF haptic output device comprises a signal electrode that includes an insulation layer and a conductive layer positioned proximate to the insulation layer and the conductive layer is electrically coupled to a voltage supply to receive an amount of voltage for generating an ESF haptic effect, which can include a dynamic ESF haptic effect or a static ESF haptic effect. The ESF haptic output device can output the ESF haptic effect to the surface of the computing device to which the ESF haptic output device is coupled.

Abstract: Example systems and methods for haptifying virtual objects using smart stickers are taught. One example sticker device includes a haptic output device; a non-transitory computer-readable medium storing processor-executable instructions; and a processor in communication with the haptic output device, and the non-transitory computer-readable medium, the processor configured to execute the processor-executable instructions to: receive a sensor signal from the sensor; determine a haptic effect based on the sensor signal; and transmit a haptic signal to the haptic output device to cause the haptic output device to output a haptic effect.

Abstract: Systems and methods for deformation and haptic effects are disclosed. For example, one method includes the steps of receiving a sensor signal from a sensor, the sensor signal indicating a contact with a device and a location of the contact on the device; determining a deformation effect based on the contact and the location of the contact, the deformation effect configured to cause a change in a shape of the device; and outputting the deformation effect to a deformation device configured to change the shape of the device.

Abstract: A method includes displaying information via a first display, displaying information via a second display, controlling the information displayed via the first display and the second display with a controller, and receiving a first input from a user through a user interface. The first input includes a command to change a setting of the first display or the second display and/or the information being displayed via the first display or the second display. The method also includes generating a first haptic effect to confirm receipt of the first input.

Abstract: The present disclosure is generally directed to systems and methods for providing haptic effects based on information complementary to multimedia content. For example, one disclosed method includes the steps of receiving multimedia data comprising multimedia content and complementary data, wherein the complementary data describes the multimedia content, determining a haptic effect based at least in part on the complementary data, and outputting the haptic effect while playing the multimedia content.

Abstract: Systems and methods for generating haptic effects associated with envelopes in audio signals are disclosed. One disclosed system for outputting haptic effects includes a processor configured to: receive an audio signal; determine an envelope associated with the audio signal; determine a haptic effect based in part on the envelope; and output a haptic signal associated with the haptic effect.

Abstract: An actuator system configured to generate a haptic effect, the actuator system including a housing of an electronic device, the housing being configured to form a mechanical ground, a first actuator disposed between a first moving mass and the mechanical ground, the first actuator being configured to render the haptic effect, and a second actuator disposed between a second moving mass and the mechanical ground, the second actuator being configured to dampen the haptic effect.

Abstract: A haptic peripheral includes a housing and a haptically-enhanced user input element. The haptically-enhanced user input element is configured to receive an input from a user, and includes a mechanical key having a keycap with a user contact surface configured to contact the user and a smart material actuator integrated onto the user contact surface of the keycap. The smart material actuator is configured to receive a control signal from a processor and is configured to deform at least a portion of the user contact surface relative to the keycap of the mechanical key in response to the control signal from the processor to thereby provide a haptic effect to a user of the haptic peripheral. The haptic peripheral may also include a braking actuator coupled to the mechanical key to hold the mechanical key in a depressed position to indicate an inactive status to a user. In addition, the haptic peripheral and the haptically-enhanced user input element may be modular.

Abstract: Interactive content may be presented to a user that is manipulating a peripheral. One or more state parameters that are related to the position of the peripheral may be determined. The peripheral may be identified from a plurality of possible peripherals. The interactive content may be adjusted based at least in part on the one or more position parameters and/or the identification of the peripheral. Haptic feedback to be provided to the user may be determined based at least in part on the one or more position parameters and/or the identification of the peripheral.

Abstract: A system having a haptic control unit, a haptic delivery cluster, and an electric field generator, magnetic field generator, or pneumatic actuator is presented. The haptic delivery cluster comprises a plurality of haptic delivery nodes, wherein each haptic delivery node of the plurality of haptic delivery nodes is separate from other haptic delivery nodes of the plurality of haptic delivery nodes, is at least one of a wireless communication device, a sensor, or a computing device, and has a dimension that is less than or equal to 5 mm. The electric field generator, magnetic field generator, or pneumatic actuator is in communication with the haptic control unit and is configured, when activated, to generate an electric field or a magnetic field in a physical environment in which the haptic delivery cluster is located, or to output a pulse of air in the physical environment.

Abstract: A haptic effect enabled system generates a haptic effect using an electric potential responsive fluid. A haptic enabled apparatus includes a fluid and a substrate. The fluid is responsive to an electric field. The substrate is at least partially flexible and defines a channel. The fluid is positioned within at least a portion of the channel. A portion of the substrate proximal to the fluid is stiffer than a portion of the substrate spaced from the fluid, thereby creating a haptic effect.

Abstract: One illustrative system disclosed herein includes a processor configured to receive a sensor signal from a neural interface configured to detect an electrical signal associated with a nervous system. The processor is also configured to determine an interaction in with a virtual object in a virtual environment based on the sensor signal. The processor is also configured to determine a haptic effect based at least in part on the interaction with the virtual object in the virtual environment. The processor is also configured to transmit a haptic signal associated with the haptic effect. The illustrative system further includes a haptic output device configured to receive the haptic signal and output the haptic effect.

Abstract: Examples of externally-activated devices and systems are disclosed. One example system includes a first device having an actuation component; and a second device having a haptic output component, wherein: the first device and the second device are configured to be physically separable from each other; the actuation component is configured to transmit an actuation signal to the haptic output component while the first device and the second device are physically separated from each other, and the haptic output component configured to output a haptic effect in response to receiving the actuation signal and while the first device and the second device are physically separated from each other, the haptic effect based on the actuation signal.

Abstract: Systems and methods long-range interactions for virtual reality are disclosed. One disclosed system includes: a handheld interface device; a sensor configured to detect movement of the handheld interface device and transmit a sensor signal associated with the movement; a processor coupled to the sensor and configured to: determine a haptic signal based in part on the sensor signal; and control, based on the haptic signal, an electromagnetic source remote from the handheld interface device to output a magnetic field to apply a force to magnetic material in the handheld interface device to output a haptic effect to a user of the handheld interface device.

Abstract: This disclosure relates to systems and haptic actuators, and suitably haptic actuation resulting from the response to a magnetic field of magnetic particles within an elastomeric material. Such systems and haptic actuators are useful in structural materials, including as elements of wearables or accessories, as well as in other applications and devices where haptic feedback is desired.