Disclosed is an intelligent measurement cup, comprising a cup body and a cup cover, which covers the cup body and has an electronic module provided therein. The electronic module comprises a battery, a main control circuit board electrically connected to the battery, and a laser detection unit electrically connected to the main control circuit board. The laser detection unit comprises a laser probe and a transparent shielding sheet which covers the laser probe. The laser probe is arranged at a side facing toward the cup body. A through hole is formed in the cup cover in a manner of corresponding to the laser probe so as to allow light of the laser probe to pass through. A laser emitted from the laser probe penetrates the shielding sheet and is then incident in the cup body in a scattered manner, so as to ensure that sufficient feedback photons are formed. The spectra reflected back through different emission media are different, therefore, the conditions of a liquid, conditions comprising the remaining amount, the type, whether the liquid has deteriorated, etc., in the cup body can be accurately detected.

Systems and methods for providing a smart hydration container or bottle which accurately tracks a user's liquid intake. The smart hydration container utilizes a new capacitive sensing technology which does not require a complicated design for capacitive conductive surfaces and provides accurate capacitive measurements which map to volume measurements. Through the use of calibrated data, the smart hydration container accurately measures capacitance “as a whole” of the entire container's contents even when the container is not resting upright. In some implementations, the smart hydration container utilizes a combination of capacitive sensing, motion sensing, position sensing, and/or temperature sensing to provide an accurate measure of liquid volume in the container. The capacitive sensor may be electrically shielded by a passive conductive sensor shield, a grounded conductive sensor shield, or an active conductive sensor shield.

Systems and methods for providing a smart hydration container or bottle which accurately tracks a user's liquid intake. The smart hydration container utilizes a new capacitive sensing technology which does not require a complicated design for capacitive conductive surfaces and provides accurate capacitive measurements which map to volume measurements. Through the use of calibrated data, the smart hydration container accurately measures capacitance “as a whole” of the entire container's contents even when the container is not resting upright. In some implementations, the smart hydration container utilizes a combination of capacitive sensing, motion sensing, position sensing, and/or temperature sensing to provide an accurate measure of liquid volume in the container. The capacitive sensor may be electrically shielded by a passive conductive sensor shield, a grounded conductive sensor shield, or an active conductive sensor shield.

Liquid consumption devices, systems, and methods of using the same are described herein. One method of using a liquid consumption device can comprise determining a hydration plan for a user based on parameters of the user using a computing system, receiving data from a liquid consumption device at the computing system over a period of time, aggregating the data received over the period of time to track liquid consumption of the user, and identifying the user is outside a threshold hydration level based on the aggregated data and the determined hydration plan.

Liquid consumption devices, systems, and methods of using the same are described herein. One method of using a liquid consumption device can comprise determining a hydration plan for a user based on parameters of the user using a computing system, receiving data from a liquid consumption device at the computing system over a period of time, aggregating the data received over the period of time to track liquid consumption of the user, and identifying the user is outside a threshold hydration level based on the aggregated data and the determined hydration plan.

The invention discloses a method of filling beverage into a beverage vessel, comprising the following steps: selecting at least one beverage by a program running on a personal electronic device having a personal electronic device processor by a user, wherein the at least one beverage is represented by at least one beverage parameter set and wherein the at least one beverage parameter set is stored in beverage data; positioning the beverage vessel in the proximity of the personal electronic device by the user; emitting an RF field by an antenna of the personal electronic device; transmitting the beverage data from an the antenna of the personal electronic device in a radio message to an antenna of the beverage vessel by near field communication controlled by the personal electronic device processor after presence of the beverage vessel in the proximity of the personal electronic device has been detected by the personal electronic device by near field communication; extracting electric energy from the RF field by the vessel antenna; storing the beverage data in a memory of the beverage vessel controlled by a vessel processor after receiving the beverage data by the antenna of the beverage vessel; positioning the beverage vessel in the proximity of a beverage dispenser by a user; transmitting a RF field from an antenna of the beverage dispenser; after detecting the beverage vessel in the proximity of the beverage dispenser by near field communication, transmitting by near field communication under control of a dispenser controller by the beverage dispenser a request command from an the antenna of the beverage dispenser to the antenna of the beverage vessel requesting to transmit beverage data in a radio message; extracting electric energy from the RF field by the vessel antenna; in response to receiving the request command by the beverage vessel, reading the beverage data from the memory of the beverage vessel and transmitting the beverage data by the antenna of the beverage vessel to the antenna of the beverage dispenser by near field communication under control of the vessel processor; and in response to receiving the beverage data by the antenna of the beverage dispenser outputting one of the at least one beverage defined by the beverage parameter set in the beverage data into the beverage vessel under control of the dispenser controller, wherein the portable beverage vessel comprises a container comprising a bottom portion forming the lower end of the container and a wall extending from the bottom portion in an essentially vertical direction; a magnetic coupling element arranged at the container; and a control device having a complementary magnetic coupli

This disclosure includes a description of an electronically enabled drinking receptacle that has a liquid container, an electronic processor, an electronic drinking monitor, and a user-communicator. The drinking monitor can provide information to the electronic processor regarding an amount of liquid withdrawn from the liquid container over time and the electronic processor can be configured to actuate the user-communicator to communicate information to a user. The user-communicator can include one or more lights on the drinking receptacle, and the information communicated to the user can be configured to encourage the user to drink more liquid. The drinking receptacle can include an electronic communicator configured to communicate information between the liquid container and a separate electronic device, which can be remote from the drinking receptacle. The separate electronic device can be a mobile electronic device such as a wearable mobile electronic device.

This disclosure includes a description of an electronically enabled drinking receptacle that has a liquid container, an electronic processor, an electronic drinking monitor, and a user-communicator. The drinking monitor can provide information to the electronic processor regarding an amount of liquid withdrawn from the liquid container over time and the electronic processor can be configured to actuate the user-communicator to communicate information to a user. The user-communicator can include one or more lights on the drinking receptacle, and the information communicated to the user can be configured to encourage the user to drink more liquid. The drinking receptacle can include an electronic communicator configured to communicate information between the liquid container and a separate electronic device, which can be remote from the drinking receptacle. The separate electronic device can be a mobile electronic device such as a wearable mobile electronic device.

System and method for identification and verification of authorization of a subject to use a substance delivery device.

Method for monitoring the use of a drinking bottle and a system for carrying out the method. A drinking bottle is designed to detect, on the basis of sensor data of at least one sensor, whether the dispensing of liquid from the drinking bottle is caused by drinking and to distinguish this from dispensing processes which do not represent drinking processes. An evaluation system collects sensor data of the at least one sensor. The evaluation system evaluates this sensor data, and if the dispensing was caused by a drinking process, stores the number of drinking processes and/or the volume of the liquid dispensing caused by drinking.