The present disclosure concerns an aerosol generation device comprising a wicking element, a heating assembly configured to heat the wicking element, a removable capsule configured to contain a vaporizable material and having an aperture through which the vaporizable material can flow. The device comprises a valve arranged on the removable capsule, the valve having a closed position in which the aperture is closed to retain the vaporizable material in the removable capsule and an open position in which the aperture is open to release the vaporizable material from the removable capsule toward the wicking element. The heating assembly is configured to operate a drying cycle of the wicking element upon detection of a valve position by a valve detector.

A display is provided for an aerosol-generating device, the display including: a notification window; and a nano-photonic material extending over a front surface of the notification window, the nano-photonic material being configured to, in response to a light wave comprising at least one predetermined wavelength backlighting the notification window and being incident on the nano-photonic material, increase an amplitude of the at least one predetermined wavelength and emit therefrom a light wave comprising the at least one predetermined wavelength with the increased amplitude. An aerosol-generating device including the display is also provided.

An apparatus and a method for an aerosol generating device is described, the apparatus including a charging controller. The charging controller is configured to control charging of a battery using a power supply at a charging current dependent, at least in part, on power capabilities of the power supply.

An apparatus and a method for an aerosol generating device is described, the apparatus including a charging controller. The charging controller is configured to control charging of a battery using a power supply at a charging current dependent, at least in part, on power capabilities of the power supply.

An aerosol-generating apparatus includes a housing comprising at least one light-transmitting window configured to transmit external light to an inside of the aerosol-generating apparatus; a heating element comprising a plurality of nanoparticles configured to generate heat in response to light through Surface Plasmon Resonance (SPR); a light source arranged inside the housing and configured to emit light toward the heating element; a sensor configured to detect a temperature of the heating element or a quantity of the external light transmitted to the inside of the aerosol-generating apparatus through the at least one light-transmitting window; and a processor configured to adjust a quantity of light received by the heating element by controlling the light source based on the detected temperature of the heating element or the detected quantity of the external light transmitted to the inside of the aerosol-generating apparatus.

The present disclosure relates to aerosol delivery devices comprising a power unit and a cartridge that is configured for engagement with the power unit. In particular, the cartridge can be configured for rotation about a longitudinal axis thereof so as to be insertable into a chamber of the power unit in a plurality of different orientations. Further, the aerosol delivery device can include processing circuitry that can be configured for detection of the cartridge orientation and execution of a control function assigned to the respective orientation.

The present disclosure relates to an aerosol delivery device and related methods and computer program products for controlling an aerosol delivery device based on input characteristics. For example, a method may include an aerosol delivery device determining a characteristic of a user input to the aerosol delivery device. The method may further include the aerosol delivery device determining a control function having a defined association with the characteristic. The method may additionally include the aerosol delivery device performing the control function in response to the user input.

Provided is an aerosol generating apparatus including: a heater configured to generate aerosol by heating a cigarette, the heater including a first electrically conductive heating element formed along a first path on an electrically insulating substrate, a second electrically conductive heating element formed along a second path on the electrically insulating substrate, and a temperature sensor track formed along a third path in a region between the first path and the second path; a battery configured to supply power to the heater; and a controller configured to control the power supplied from the battery to the heater and monitor a temperature sensed using the temperature sensor track.

Provided is an aerosol generating apparatus including: a heater configured to generate aerosol by heating a cigarette, the heater including a first electrically conductive heating element formed along a first path on an electrically insulating substrate, a second electrically conductive heating element formed along a second path on the electrically insulating substrate, and a temperature sensor track formed along a third path in a region between the first path and the second path; a battery configured to supply power to the heater; and a controller configured to control the power supplied from the battery to the heater and monitor a temperature sensed using the temperature sensor track.

A power supply unit for an aerosol inhaler includes: a power supply able to discharge power to a load for generating an aerosol from an aerosol source; a connector able to be electrically connected to an external power supply; a control device configured to control at least one of charging and discharging of the power supply or configured to be able to convert power which is input from the connector into charging power for the power supply; and a zener diode provided between the connector and the control device so as to be connected in parallel with the control device. A maximum value of zener voltage of the zener diode is lower than a maximum operation guarantee voltage of the control device.