A method of authenticating a consumable for use with an aerosol generating device, includes initiating a communication between the aerosol generating device and a first entity to obtain the consumable from the first entity for use with the aerosol generating device, the aerosol generating device being associated with a device ID and the consumable being associated with a consumable ID; sending the device ID and the consumable ID from the first entity to a second entity, wherein the second entity is configured to associate and store the device ID with the consumable ID; and verifying use of the consumable with the aerosol generating device.

A sensing module for monitoring dosage delivery of a vaporized material, and a portable vaporization unit including the sensing module, include a light sensor that detects disruptions in a light path across a vapor channel, the disruptions caused by the vaporized material flowing through the vapor channel. The light sensor includes a UV light source, which may emit 370 nm wavelength light, and a UV light detector that converts intensity of incident light in the light path into a signal. A microprocessor of the sensing module compares the signal to a baseline measurement to determine the concentration of a medicament in the vapor; then, using the flow rate and activation time of the device, the microprocessor determines the dosage and can perform monitoring and reporting actions based on the dosage. A measuring circuit measures fluctuations in resistance/impedance of a vaporization element to further determine flow rate and/or dosage.

A sensing module for monitoring dosage delivery of a vaporized material, and a portable vaporization unit including the sensing module, include a light sensor that detects disruptions in a light path across a vapor channel, the disruptions caused by the vaporized material flowing through the vapor channel. The light sensor includes a UV light source, which may emit 370 nm wavelength light, and a UV light detector that converts intensity of incident light in the light path into a signal. A microprocessor of the sensing module compares the signal to a baseline measurement to determine the concentration of a medicament in the vapor; then, using the flow rate and activation time of the device, the microprocessor determines the dosage and can perform monitoring and reporting actions based on the dosage. A measuring circuit measures fluctuations in resistance/impedance of a vaporization element to further determine flow rate and/or dosage.

An aerosol-generating device is provided, including: at least two heating arrangements, each heating arrangement including a heating coil, first, second, and third contacts, the first contact being arranged contacting a distal end of the heating coil, the second contact being arranged contacting a proximal end of the heating coil, and the third contact being arranged contacting the heating coil between the first and second contacts, and a sliding arrangement, the heating coils being arranged side by side parallel to a longitudinal axis of the device, the sliding arrangement being arranged adjacent the heating coils and configured to slide parallel to the longitudinal axis and parallel to the heating coils, the third contacts being mounted on the sliding arrangement, and an electrical contact point between each third contact and each respective heating coil being adaptable by sliding the sliding arrangement.

An aerosol-generating device is provided, including: at least two heating arrangements, each heating arrangement including a heating coil, first, second, and third contacts, the first contact being arranged contacting a distal end of the heating coil, the second contact being arranged contacting a proximal end of the heating coil, and the third contact being arranged contacting the heating coil between the first and second contacts, and a sliding arrangement, the heating coils being arranged side by side parallel to a longitudinal axis of the device, the sliding arrangement being arranged adjacent the heating coils and configured to slide parallel to the longitudinal axis and parallel to the heating coils, the third contacts being mounted on the sliding arrangement, and an electrical contact point between each third contact and each respective heating coil being adaptable by sliding the sliding arrangement.

An aerosol-generating device configured to receive an aerosol-generating article is provided, including: an elongate housing having a distal end and a proximal end; a light source; and a controller configured to control the light source, in which, in use, the proximal end of the housing points towards a consumer, in which the proximal end of the housing includes an illumination portion made from translucent material, in which the light source is optically coupled to the illumination portion, and in which the illumination portion is configured to surround the aerosol-generating device in use. An aerosol-generating system including the aerosol-generating device and an aerosol-generating article is also provided. A method of operating the aerosol-generating system is also provided.

An aerosol-generating device is provided, including: an elongate housing having a distal end and a proximal end and being configured to receive an aerosol-generating article, the elongate housing defining a heating chamber having an open end at the proximal end of the aerosol-generating device, the heating chamber being configured for insertion of an aerosol-generating article, in which during consumption the proximal end of the aerosol-generating device points towards a consumer, in which the proximal end of the aerosol-generating device includes a visual feedback means, and in which the visual feedback means surrounds the aerosol generating article, when received in the aerosol-generating device. An aerosol-generating system, and a method of operating an aerosol-generating system, are also provided.

Systems and methods of an electronic drug delivery system for use in a treatment program (e.g., a smoking cessation program). The delivery system can include a mobile platform and a hand-held inhalation delivery device having a controller circuit coupled to a power source, sensors, aerosolizer drivers, and a rescue button, and a pod removably coupled to the delivery device. The delivery system generates an aerosol mixture from substances in the pod in accordance with the treatment program, and delivers the aerosol mixture for inhalation by a user. The controller circuit individually and dynamically controls the aerosolizer drivers to generate signals that drive a plurality of thermal, or non-thermal, aerosolizers of the pod to generate individually tailored aerosol mixtures from multiple substances in the aerosolizer pod. The generated aerosol mixtures can have various percentages of the substances, and have different aerosol droplet sizes during different portions of the treatment program.

Systems and methods of an electronic drug delivery system for use in a treatment program (e.g., a smoking cessation program). The delivery system can include a mobile platform and a hand-held inhalation delivery device having a controller circuit coupled to a power source, sensors, aerosolizer drivers, and a rescue button, and a pod removably coupled to the delivery device. The delivery system generates an aerosol mixture from substances in the pod in accordance with the treatment program, and delivers the aerosol mixture for inhalation by a user. The controller circuit individually and dynamically controls the aerosolizer drivers to generate signals that drive a plurality of thermal, or non-thermal, aerosolizers of the pod to generate individually tailored aerosol mixtures from multiple substances in the aerosolizer pod. The generated aerosol mixtures can have various percentages of the substances, and have different aerosol droplet sizes during different portions of the treatment program.

An aerosol generating device for generating aerosol from an aerosol generating material is disclosed. The aerosol generating device includes a first heating unit and a second heating unit both arranged to heat, but not burn, an aerosol generating material in use. A controller is arranged to control the first and second heating units wherein during the course of a session the controller is arranged to set the first heating unit: (i) a target operating temperature T1 during a time period t1-t2; (ii) a target operating temperature T2 during a time period t2-t3; (iii) a target operating temperature T3 during a time period t3-t6; and (iv) a target operating temperature T4 during a time period t6-t7; wherein temperature T1>T2>T3>T4 and time t0<t1<t2<t3<t4<t5<t6<t7.