A system and method directed to dynamic ingredient adjustment for nutrition-based recipe ingredient modification is described. The recipe ingredient modification can be based on the amount of one or more ingredients, nutrition content of the ingredients, ingredient availability, total nutritional content of an entire recipe or on a per serving size, and amount, kind, and nutrition content of any substitute ingredient used. A recipe's at least one nutritional content or value (for example, amount of fiber or total fat in gram or percentage) can be adjusted in approximately real-time while processing or measuring the ingredients on a smart scale. The system's dynamic scaling capability also provides for the substitution of ingredients or the adjustment of the quantity of ingredients even when a user is already in the middle of processing, mixing, or adding one or more ingredients based on predetermined ingredients and quantities provided in a recipe.

A weighing scale includes a scale body and a detecting board. The scale body includes a platform in contact with feet of a subject, a weighing mechanism, a signal processor, a wireless communication device, and a display screen. The detecting board is separated from the scale body and can abut against a top head of the subject and can move towards or away from the platform. At least one of the scale body and the detecting board includes a signal emitter, and at least one of the scale body and the detecting board includes a signal receiver. The signal emitter and the signal receiver measure a distance between the platform and the detecting board. The signal processor processes data of the signal emitter, the signal receiver, and the weighing mechanism, transmits processed data to the display screen and an external mobile device or server.

A system for facilitating travel includes a handheld device for weighing luggage that is electronically linked with an application server via a smart device. The device includes electronics disposed within a housing configured to conform to a luggage handle. Lifting the luggage with the device disposed against its handle causes the luggage weight to impart a force onto the housing. This force is sensed by the electronics and converted into a weight measurement that is displayed on the smart device and sent to the application server. Weight measurements stored on the application server can be integrated with airline flight information, such as baggage restrictions, to provide certain advantages. For instance, weight measurements can be retrieved by a traveler to ensure baggage compliance. Additionally, historical luggage data can reviewed by an airline on a flight-based level to prepare for atypical cargo loads or on a traveler-basis to incentivize light baggage travel.

An inventory management system includes a floor-based weighing subsystem and a load status subsystem. The floor-based weighing subsystem includes a sensor arrangement that includes at least one weight sensor functionally associated with a load carrying unit that supports a load having an associated weight. The load carrying unit is deployed at the floor of a retail display area, and the weight sensor determines the weight of the load. A load status determination engine of the load status subsystem receives, from the floor-based weighing subsystem, the weight of the load determined by the weight sensor, and determines a loading status of the load carrying unit based on the received weight of the load.

The invention is a monitoring system for determining a vehicle maintenance condition based on weight. The system includes a monitoring station, a weight determination system, a data input device configured to receive input data, and a processing device. The processing device includes a processor and non-volatile memory. The processor is configured to receive load ratings for a tow vehicle and tow equipment, receive maintenance requirements for the tow vehicle and the tow equipment, receive vehicle use requirements for the tow vehicle and the tow equipment, receive weight data from the weight determination system, and receive the input data from the data input device. Additionally, the processor is configured to determine at least one maintenance condition based on the load ratings, the weight data, and the input data. The processor is also configured to send the maintenance condition data to the monitoring system and communicate the maintenance condition to a user.

The invention is a monitoring system for determining a vehicle safety setting based on weight. The system includes a monitoring station, a weight determination system, a data input device configured to receive input data, and a processing device. The processing devices includes a processor and non-volatile memory. The processor is configured to receive load ratings for a tow vehicle and tow equipment, receive weight data from the weight determination system, and receive the input data from the data input device. The processor is also configured to determine at least one safety setting based on the load ratings, the weight data, and the input data, send the safety setting data to the monitoring system, and communicate the safety setting to a user.

An inventory management system includes a floor-based weighing subsystem and a load status subsystem. The floor-based weighing subsystem includes a sensor arrangement that includes at least one weight sensor functionally associated with a load carrying unit that supports a load having an associated weight. The load carrying unit is deployed at the floor of a retail display area, and the weight sensor determines the weight of the load. A load status determination engine of the load status subsystem receives, from the floor-based weighing subsystem, the weight of the load determined by the weight sensor, and determines a loading status of the load carrying unit based on the received weight of the load.

A system includes modules forming an array. Each module is coupled to a neighboring module and includes flexures. Each flexure is configured to measure a load value of the module. A module board is connected to the flexures, configured to receive the load value and combine into a load module output. The load module output is within an initial module output range. A resistor is configured to set the initial module output range, which is the same for each module in the array. A microcontroller is configured to receive an input for the initial module output range, which is a difference between an output for a full-load state and a zero-load state, and configured to receive the load module output of each module, convert the load module output into a bit number, scale the bit number to generate an adjusted bit number. This represents a weight applied to the array.

An information processing device includes a controller configured to execute acquiring a detection value obtained by detecting an amount of a product stored in a storage location corresponding to the product by a sensor, and transmitting a notification regarding a storage error of the product to a user terminal in a case where a decrease amount of the product based on the detection value of the sensor in a predetermined period is larger than a threshold value.

This disclosure describes a collection bin for a waste collection vehicle. The collection bin includes a weighing system with a processor for measuring the weight of material collected from each waste container and associating this weight with appropriate data, such as the owner of the waste container.