An aerosol-generating device may comprise a housing defining at least one internal compartment. The housing may be waterproof. The aerosol-generating device may further comprise a power supply, an electric heater, and/or a haptic feedback device. Each of the power supply, electric heater, and/or haptic feedback device may be positioned within one or more of the at least one internal compartment.

An aerosol-generating device may comprise a housing defining at least one internal compartment. The housing may be waterproof. The aerosol-generating device may further comprise a power supply, an electric heater, and/or a haptic feedback device. Each of the power supply, electric heater, and/or haptic feedback device may be positioned within one or more of the at least one internal compartment.

The present invention relates to tactile warning panels, and in particular to tactile warning panels that are designed and built with multifunction/multipurpose capabilities that serve the visually impaired and enable the deployment of smart city technology by integrating tactile warning systems and subsurface enclosures that can withstand pressures of five (5) tons up to and exceeding sixty (60) tons and incorporate small cells, beacons, sensors, Fog Computing, electric energy generation, rechargeable power supplies, wireless M2M communication and a plethora of other smart city technologies.

The present invention relates to tactile warning panels, and in particular to tactile warning panels that are designed and built with multifunction/multipurpose capabilities that serve the visually impaired and enable the deployment of smart city technology by integrating tactile warning systems and subsurface enclosures that can withstand pressures of five (5) tons up to and exceeding sixty (60) tons and incorporate small cells, beacons, sensors, Fog Computing, electric energy generation, rechargeable power supplies, wireless M2M communication and a plethora of other smart city technologies.

A personal navigation system includes a sensing suite (50) that is configured to find a safety route for a person; a set of modules (200) including a generation module that is configured to generate an auditory-haptic content (70) that is not perceived visually but perceived by auditory sense or haptic sense and indicates the found safety route; and a communication device (30) that is configured to communicate the auditory-haptic content to the person.

A personal navigation system includes a sensing suite (50) that is configured to find a safety route for a person; a set of modules (200) including a generation module that is configured to generate an auditory-haptic content (70) that is not perceived visually but perceived by auditory sense or haptic sense and indicates the found safety route; and a communication device (30) that is configured to communicate the auditory-haptic content to the person.

A slim type tactile feedback device is disclosed, including: a substrate, at least an overlapping plate, a support frame, a plurality of cushions and a vibration source; the overlapping plate being fixed to the substrate in a cantilever manner; the support frame including a frame, a void area, and at least a protruding support, the protruding support being a partial segment of the frame; the cushions being fixed between the substrate and the frame; the vibration source including a magnet set and a coil set, the magnet set and the coil set being fixed between the protruding support and the overlapping plate and located at outer side the substrate; the coil set and the magnet set being positioned correspondingly to each other and separated by a gap, the gap increasing when the substrate being pressed by finger, and the substrate moving back-and-forth through linkage motion of the vibration source.

A slim type tactile feedback device is disclosed, including: a substrate, at least an overlapping plate, a support frame, a plurality of cushions and a vibration source; the overlapping plate being fixed to the substrate in a cantilever manner; the support frame including a frame, a void area, and at least a protruding support, the protruding support being a partial segment of the frame; the cushions being fixed between the substrate and the frame; the vibration source including a magnet set and a coil set, the magnet set and the coil set being fixed between the protruding support and the overlapping plate and located at outer side the substrate; the coil set and the magnet set being positioned correspondingly to each other and separated by a gap, the gap increasing when the substrate being pressed by finger, and the substrate moving back-and-forth through linkage motion of the vibration source.

Disclosed are methods to manipulate a given parametrized haptic curve in order to yield a smooth phase function for each acoustic transducer which minimizes unwanted parametric audio. Further, the impulse response of a haptic system describes the behavior of the system over time and can be convolved with a given input to simulate a response to that input. To produce a specific response, a deconvolution with the impulse response is necessary to generate an input.

Disclosed are methods to manipulate a given parametrized haptic curve in order to yield a smooth phase function for each acoustic transducer which minimizes unwanted parametric audio. Further, the impulse response of a haptic system describes the behavior of the system over time and can be convolved with a given input to simulate a response to that input. To produce a specific response, a deconvolution with the impulse response is necessary to generate an input.