There is provided an apparatus (200, 300, 400, 500) comprising: a container (210, 310, 410, 510) configured to receive a food stuff, a base unit (220, 320, 420, 520) comprising a mounting member and a plurality of outer supporting members (324, 424, 524), a weight sensing unit (230, 330, 430, 530) configured to measure a weight of the food stuff contained in the container, and a connection assembly (240, 340, 440, 540) arranged between the container and the base unit. The weight sensing unit comprises a plurality of strain gauge load sensors arranged at the mounting member of the base unit, and the connection assembly is configured to provide a flexible and insulating connection between the container and the base unit so as to counteract thermal strain interference at the weight sensing unit and to reduce heat transfer between the container and the weight sensing unit.

A system of calculating a payload weight, the system including: a first sensor configured to assist in determining an actuator load associated with a ram, the ram being connected to a lifting member; and a calibration module configured to retrieve a calibration factor based on movement of the ram, the calibration factor being applied to the actuator load to thereby provide an adjusted actuator load; wherein the payload weight is calculated based on the adjusted actuator load.

A system of calculating a payload weight, the system including: a first sensor configured to assist in determining an actuator load associated with a ram, the ram being connected to a lifting member; and a calibration module configured to retrieve a calibration factor based on movement of the ram, the calibration factor being applied to the actuator load to thereby provide an adjusted actuator load; wherein the payload weight is calculated based on the adjusted actuator load.

An overload detection processing apparatus, an overload detection system and a computer-readable recording medium storing a program capable of determining overload more accurately are provided. An overload detection processing apparatus for determining a vehicle whose loading weight exceeds a predetermined reference is provided with a processor. The processor acquires a determination value relating to magnitude of deformation of a tire from image data obtained by photographing the tire of the vehicle and determines whether or not the loading weight of the vehicle exceeds a predetermined reference based on data corresponding to the determination value and a situation relating to the tire.

An overload detection processing apparatus, an overload detection system and a computer-readable recording medium storing a program capable of determining overload more accurately are provided. An overload detection processing apparatus for determining a vehicle whose loading weight exceeds a predetermined reference is provided with a processor. The processor acquires a determination value relating to magnitude of deformation of a tire from image data obtained by photographing the tire of the vehicle and determines whether or not the loading weight of the vehicle exceeds a predetermined reference based on data corresponding to the determination value and a situation relating to the tire.

A system of hardware and software for determining the weight and center of gravity location of an airplane or other vehicles, like a forklift, truck, maritime vessel. The same system could be used to determine stresses or movement on stationary structures is disclosed. This system employs commercially available, off the shelf or existing, proven, and inexpensive technology and utilizes empirical data. Further, it is designed as a supplemental check on calculated results, which are subject to data errors and are circumvented by this invention's equipment. The system includes a set of pressure and load, strain, bending, and/or other sensors, a voltage source, a voltmeter, a computer, a display, an empirically derived database, a temperature sensor, a set of switches, wireless transmission, and a power source that allows the system to be used for determining the weight and center of gravity location of an airplane or other vehicle.

A system of hardware and software for determining the weight and center of gravity location of an airplane or other vehicles, like a forklift, truck, maritime vessel. The same system could be used to determine stresses or movement on stationary structures is disclosed. This system employs commercially available, off the shelf or existing, proven, and inexpensive technology and utilizes empirical data. Further, it is designed as a supplemental check on calculated results, which are subject to data errors and are circumvented by this invention's equipment. The system includes a set of pressure and load, strain, bending, and/or other sensors, a voltage source, a voltmeter, a computer, a display, an empirically derived database, a temperature sensor, a set of switches, wireless transmission, and a power source that allows the system to be used for determining the weight and center of gravity location of an airplane or other vehicle.

A method for adjusting parameters of a device with a weighing sensor collecting environmental parameter data of an environment where the device is currently located or environmental parameter data during execution of an application by the device. A zero compensation parameter is calculated and updated, based on the data collected. The method is applicable to a moisture analyzer and also to a vehicle scale. In the moisture analyzer, the method is triggered and executed in the analyzer, correcting the zero compensation data by using the environmental parameter data of an environment or environmental parameter data during execution of an application by the analyzer. Dynamic and real-time adjustment of a compensation parameter overcomes the problem that the scheme of pre-setting fixed parameters for zero compensation cannot deal with the complex zero drift encountered in actual environments.

A system and method for measuring the weight of a user using an scale, the scale having an inflatable pouch with a fluid pressure sensor and a temperature sensor placed therein; a processing circuitry connected to the fluid pressure sensor and the temperature sensor; a communication interface connected to the processing circuitry; wherein the fluid pressure sensor is configured to determine an internal pressure from the fluid pressure sensor, and the temperature sensor is configured to determine an internal temperature within the inflatable pouch; wherein the processing circuitry is configured to calculate a weight of an object placed on the inflatable pouch based on the determined internal pressure and internal temperature; and wherein the processing circuitry is configured to relay the calculated weight of the object to a user device via the communication interface.

A system and method for measuring the weight of a user using an scale, the scale having an inflatable pouch with a fluid pressure sensor and a temperature sensor placed therein; a processing circuitry connected to the fluid pressure sensor and the temperature sensor; a communication interface connected to the processing circuitry; wherein the fluid pressure sensor is configured to determine an internal pressure from the fluid pressure sensor, and the temperature sensor is configured to determine an internal temperature within the inflatable pouch; wherein the processing circuitry is configured to calculate a weight of an object placed on the inflatable pouch based on the determined internal pressure and internal temperature; and wherein the processing circuitry is configured to relay the calculated weight of the object to a user device via the communication interface.