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: 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: 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: Systems and methods for using textures in graphical user interface widgets are disclosed. For example, one disclosed system includes: a processor configured to: receive an interface signal from a touch-sensitive interface associated with a display area; receive a display signal associated with the display area, the display signal comprising a plurality of pixels associated with one or more colors; assign a haptic value to each color; determine a texture associated with a group of the plurality of pixels by determining the haptic value associated with the group of the plurality of pixels; determine a selected actuator by selecting a first actuator if the haptic value is less than a threshold and selecting a second actuator if the haptic value is greater than or equal to the threshold; and transmit a haptic signal configured to cause the selected actuator to output a haptic effect configured to simulate the texture.

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.

Abstract: A device for delivering non-collocated haptic feedback includes at least one haptic playback device and a drive circuit for controlling the haptic playback device. A processor coupled to the drive circuit receives manipulation haptic information based on data received from a user interface. The processor generates a haptic signal is based on the manipulation haptic information. The haptic signal is provided to the drive circuit to produce the non-collocated haptic feedback.

Abstract: A method and system for avoiding haptic effects conflict is presented. A haptic enabled device configured to generate haptic effects associated with a first signature is used by a user. The system detects an additional source of haptic effects and determines a second signature associated with the haptic effects produced by the source. The system determines a preferred set of haptic configurations and modifies either the first or second signature based on the preferred set of haptic configurations to achieve a minimal conflict between the first and second signatures.

Abstract: Systems and methods for providing haptic effects are disclosed. For example, one disclosed system includes a computer-readable medium having program code, the program code including program code defining a haptic widget. The haptic widget includes program code defining a haptic effect; program code defining an interface for the haptic widget; program code for receiving, via the interface, a configuration of at least one parameter of the haptic widget; program code for receiving, via the interface, a play command for the haptic effect; and program code for outputting, via the interface, a signal configured to cause the haptic effect, the signal based on the at least one parameter and in response to the play command.

Abstract: A system provides haptic functionality. The system determines a location of a body area of a user relative to a location of a haptic device that includes an ultrasound emitter. The system then determines a haptic effect, and projects the haptic effect to the body area of the user by the ultrasound emitter of the haptic device.

Abstract: The present application relates generally to haptic feedback actuators and their construction and use in touch based systems. The haptic feedback actuators are suitably bilayer structures including at least two materials having different thermal coefficients, allowing the structure to deflect from a first position to a second position in response to heating and/or cooling of the structure.

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 notification manager is provided that manages notifications for a user. The notification manager detects a notification event and determines a context of the notification event. The notification manager determines a target device for the notification event based on the determined context and one or more available displays. The notification manager then generates a notification on one or more of the one or more available displays to direct the user's attention to the target device.

Abstract: A system generates a haptic effect that simulates a mechanical button. The system receives a signal that indicates that a user has contacted a user interface of the system. The system includes an impact actuator. In response to the signal, a moving element of the impact actuator contacts the user interface, which generates the haptic effect.

Abstract: Rendering haptics includes applying a haptic effect proximate to a flexible joint of an individual using a haptic output device. In response, an illusion of joint movement is conveyed at the flexible joint of the individual.

Abstract: Methods, systems, and devices are described for location-based notifications for shopping assistance. One disclosed method includes the steps of receiving a list of items for a shopping list; obtaining a location of at least one of the items in the list; responsive to a determination that a proximity of a user device to the location is within a threshold proximity of the location: generating a notification signal based on the proximity of the user device to the location; and outputting the notification signal to cause the user device to output a notification.

Abstract: Systems and methods for multi-pressure interaction on touch-sensitive surfaces are disclosed. One disclosed embodiment of a method comprises receiving a first sensor signal from a touch-sensitive input device in response to a first contact of a first object on the touch-sensitive input device, the first sensor signal comprising a first location and a first pressure of the first contact, receiving a second sensor signal from the touch-sensitive input device in response to a second contact of a second object on the touch-sensitive input device substantially simultaneously with the first contact, the second sensor signal comprising a second location of the second contact and a second pressure of the second contact, generating a signal based at least in part on the first sensor signal and the second sensor signal, the signal configured to cause a haptic effect, and outputting the signal.

Abstract: A system configured to activate a hidden control includes a sensor configured to sense an input by a user. The input includes a gesture. The system includes a haptic output device configured to output a haptic feedback as the input is being sensed, and a processor configured to determine if the sensed input corresponds to a predetermined gesture associated with activation of a control, and if the sensed input corresponds to the predetermined gesture to activate the control.

Abstract: A haptic peripheral includes a housing with a frame having a plurality of circumferentially-spaced apart windows, a plurality of deformable membranes positioned within the plurality of circumferentially-spaced apart windows, and a haptic output device disposed within the housing and coupled to the plurality of deformable membranes. The haptic output device includes a motor, a converter, and a plurality of radially-extending pins. Each radially-extending pin has a first end attached to the converter and a second opposing end attached to a deformable membrane. The motor is configured to receive a control signal from a processor and is configured to rotate relative to the housing in response to the control signal. The converter converts rotary motion of the motor to linear motion to move the plurality of radially-extending pins to thereby radially extend the deformable membranes relative to the housing and provide a haptic effect to a user of the haptic peripheral.

Abstract: Systems and methods for designing haptics using speech commands are disclosed. One illustrative system described herein includes: a processor configured to: receive an audio signal from an audio capture device, the audio signal associated with vocal user interaction; determine a haptic effect based in part on the audio signal, the haptic effect configured to be output by a haptic output device; and store the haptic effect on a data store.