A method and a system measure interfering influences on a checkweighing device. In the method, external interference data are obtained, as are interference data from the checkweighing device itself and interference data from an object being weighed, by calculating or mapping the weighing error data in the stationary state, in the operating state, and in the weighing state. The system for measuring the interference uses a meter and a processing apparatus. The meter and the processing apparatus perform an interference measurement and a compensation method. The amount of interference in the checkweighing device in each state and the amount of influence of the interference on the weighing performance is obtained, thereby facilitating the production, debugging, maintenance, and use of a checkweighing device.

The present disclosure discloses a method for quick weighing of loose and small packages of traditional Chinese medicine (TCM), comprising: 1) establishing an equivalent physical model of a weighing system for loose and small packages, and, through Laplace transformation and Z transformation, obtaining a formula of the mass M of medicine packages to be weighed; 2) calculating a.sub.1, a.sub.2, b.sub.1, and b.sub.2 on the basis of a vector prediction error; 3) according to a.sub.1, a.sub.2, b.sub.1, and b.sub.2 obtained and the formula of the mass of medicine packages to be weighed, obtaining the mass of the loose and small packages of TCM that are weighed. According to the method, the scalar prediction error is expanded into the vector prediction error based on the traditional method so as to construct a new identification model based on the vector prediction error, and as a result the utilization efficiency of prediction error turns higher.

A weighing apparatus includes a conveyance unit configured to convey an article, a weighing unit configured to weigh weight of the article conveyed by the conveyance unit, a processing unit configured to process an original signal related to weighing, by a plurality of digital filters set in advance, the original signal being output from the weighing unit, and a display unit configured to display information output from processing unit, in which the processing unit is configured to generate evaluation information for each digital filter to be applied, based on a result of sequentially applying the plurality of digital filters to the original signal that is output when the conveyance unit is in operation and the article is not conveyed by the conveyance unit, and the display unit is configured to display at least one of the evaluation information.

An absolute mass balance determines an absolute mass of an object and includes: a dual diameter wheel including: a balance fulcrum; and a balance beam disposed on the balance fulcrum and including: a main mass arm and a counter mass arm; a main mass receiver that receives the object; a main magnet system including: a first main coil that produces a first magnetic field; a second main coil that produces a second magnetic field; and a permanent magnet that produces a third magnetic field that interacts with the first magnetic field and the second magnetic field; a displacement measuring system that provides a null position of the dual diameter wheel and measures a velocity of the main magnet system; and a driving motor including: an eddy current damper that provides a constant velocity of the main mass receiver; and a counter mass magnet system.

An absolute mass balance determines an absolute mass of an object and includes: a dual diameter wheel including: a balance fulcrum; and a balance beam disposed on the balance fulcrum and including: a main mass arm and a counter mass arm; a main mass receiver that receives the object; a main magnet system including: a first main coil that produces a first magnetic field; a second main coil that produces a second magnetic field; and a permanent magnet that produces a third magnetic field that interacts with the first magnetic field and the second magnetic field; a displacement measuring system that provides a null position of the dual diameter wheel and measures a velocity of the main magnet system; and a driving motor including: an eddy current damper that provides a constant velocity of the main mass receiver; and a counter mass magnet system.

The present invention relates to a calibration device (4) comprising: —at least one impact plate (5), characterized in that the device (4) also comprises: —at least one first sensor (1) embedded into a first moving object (3A), said first sensor (1) measuring the way, velocity, form of movement and impact strength directly in the first moving object (3A) hitting the impact plate (5), —at least one second moving object (3B), —at least a first radio-frequency identification transmitter with antenna (1A) embedded into the first sensor (1), —at least one second sensor (2A,2B,2C) attached directly underneath the plate (5) for determining characteristics of the first moving object (3A), when hitting the impact plate (5), —at least one first means (6) for receiving first data provided by the first sensor (1), before and while hitting the impact plate (5), and for receiving second data provided by the second sensor (2A,2B,2C), when hitting the impact plate (5), —at least a second radio-frequency identification transmitter with antenna (6A) embedded into the first means (6), —the first sensor (1) and the second sensor (2A,2B,2C) are interacting with the first means (6), —at least one second means (7) for analysing the data provided by the first sensor (1) and by the second sensor (2A,2B,2C) and for calibrating the second sensor (2A,2B,2C) located on the impact plate (5) and determining the characteristics of at least one second moving object (3B) when hitting the impact plate (5), —a high speed camera (20) is configured to assess parameters due to the impacts of the first and second moving objects on the impact plate (5).

The present invention relates to a calibration device (4) comprising: —at least one impact plate (5), characterized in that the device (4) also comprises: —at least one first sensor (1) embedded into a first moving object (3A), said first sensor (1) measuring the way, velocity, form of movement and impact strength directly in the first moving object (3A) hitting the impact plate (5), —at least one second moving object (3B), —at least a first radio-frequency identification transmitter with antenna (1A) embedded into the first sensor (1), —at least one second sensor (2A,2B,2C) attached directly underneath the plate (5) for determining characteristics of the first moving object (3A), when hitting the impact plate (5), —at least one first means (6) for receiving first data provided by the first sensor (1), before and while hitting the impact plate (5), and for receiving second data provided by the second sensor (2A,2B,2C), when hitting the impact plate (5), —at least a second radio-frequency identification transmitter with antenna (6A) embedded into the first means (6), —the first sensor (1) and the second sensor (2A,2B,2C) are interacting with the first means (6), —at least one second means (7) for analysing the data provided by the first sensor (1) and by the second sensor (2A,2B,2C) and for calibrating the second sensor (2A,2B,2C) located on the impact plate (5) and determining the characteristics of at least one second moving object (3B) when hitting the impact plate (5), —a high speed camera (20) is configured to assess parameters due to the impacts of the first and second moving objects on the impact plate (5).

A transaction terminal includes a vertically integrated bagging weigh scale and a vertically integrated scanner. The scale includes two posts that extend horizontally out from the terminal and upon which a bag hangs. Items placed in the bag cause displacement of the posts and/or pressure detected on the posts resulting in a recorded weight by a weight sensor of the scale. A current recorded weight of the bag is reported from the scale to the terminal during a transaction as each item is placed into the bag. The terminal uses the item weights to record prices for those items sold by weight and to verify that items scanned by the scanner and placed in the bag have expected weights for those items.

A transaction terminal includes a vertically integrated bagging weigh scale and a vertically integrated scanner. The scale includes two posts that extend horizontally out from the terminal and upon which a bag hangs. Items placed in the bag cause displacement of the posts and/or pressure detected on the posts resulting in a recorded weight by a weight sensor of the scale. A current recorded weight of the bag is reported from the scale to the terminal during a transaction as each item is placed into the bag. The terminal uses the item weights to record prices for those items sold by weight and to verify that items scanned by the scanner and placed in the bag have expected weights for those items.

A system of detecting loading and unloading of mobile containers such as grain carts utilizes two low pass filters to determine whether the contents of the container are changing by subtracting one filter signal from the other, and using the sign of the difference. Weighing performance is improved by utilizing accelerometers to compensate for measurement dynamics and non-level orientation. Failure and degradation of weight sensors is detected by testing sensor half bridges. Loading and unloading weights can be tied to specific vehicles by utilizing RF beacons.