Abstract: A method for calculating the quantity of goods based on weighing includes the following steps: Step 1, Weight Conversion; accurately convert the weighing reading to the corresponding weight value W; Step 2, Weight Scaling; that is, the conversion of weight units; Step 3, Zero Point Correction; calibrate the weight reading; Step 4, Tare; remove the weight of non-goods objects in the weight value; Step 5, Anti-Mutation Filtering; anti-mutation filtering on the weight value; Step 6, Quantity Conversion; convert the weight value after calibration and correction of steps 1 to 5 above into the approximate (rough) quantity of the goods; Step 7, Quantity Calibration; calibrate the rough quantity of the above-mentioned goods.

Abstract: A wheel loader includes a lift arm, bucket, a lift cylinder that rotates the lift arm, a hydraulic force detection unit that detects a hydraulic force of the lift cylinder, an arm angle detection unit that detects a rotation angle of the lift arm, and a controller that calculates a weight of the load. A hydraulic force measurement unit measures a hydraulic force with the rotation angle of the lift arm within a predetermined measurement angle range; and a hydraulic-force-change-rate calculation unit calculates a change rate of the hydraulic force with respect to the rotation angle of the lift arm, and then calculates a new hydraulic force change rate within the measurement angle range. The controller corrects an error of the weight of the load occurring due to the inclination angle of the body on the basis of the new hydraulic force change rate calculated by the hydraulic-force-change-rate calculation unit.

Abstract: An exemplary method generally involves determining a hazard parameter for a tracked vehicle including a ground interface assembly. The ground interface assembly generally includes a track and a drive wheel operable to move the track to thereby propel the tracked vehicle. A load sensor senses a load carried by the tracked vehicle, and a speed sensor senses a vehicle speed of the tracked vehicle. A control system in communication with the load sensor, the speed sensor, and a temperature sensor determines the hazard parameter based upon the load, the vehicle speed, and an ambient temperature in a vicinity of the tracked vehicle. The control system compares the hazard parameter to a threshold parameter, and performs an action based upon the comparison.

Abstract: Systems are disclosed for dispensing, weighing, identifying, processing, and/or printing tag identifiers for items (e.g., bulk food items). In one embodiment, a storage system includes a scoop bin configured to store a product, wherein the scoop bin has a lid configured to be moved between a closed position and an open position, and wherein the product is configured to be scooped out of the scoop bin by a customer when the lid is in the open position. The system further includes a sensor configured to monitor a movement of the scoop bin, wherein the sensor is configured to transmit a notification to the computing device identifying the movement of the scoop bin. A printer is configured to receive an instruction from the computing device to automatically print a label identifying the product stored in the scoop bin following the computing device receiving the notification of the movement.

Abstract: An energy balancing system scales portion sizes of user-selected meal recipes to control a digital scale to prompt the user to measure scaled quantities of meal ingredients to prepare scaled meals. Physical activity tracking devices provide data to generate physical activity energy expenditures for energy burned by physical activity. The physical activity energy is added to a basal metabolic rate of energy expenditure that is a function of sex, weight, height, and age. The total energy expended are scaled down for a weight-loss goal to obtain the total recommended energy. A recipe portion-size optimizer adjusts scaling factors for each recipe so that the total recommended energy is met by the scaled meals. Amounts of nutrients for the recipes can also be scaled by the scaling factors to match recommended nutrient amounts when the meal recipe optimizer generates the scaling factors using an over-determined linear system optimizer.

Abstract: A first processor determines a loaded state of a bucket, makes a determination that a traveling apparatus has performed an operation for shifting from a rearward movement state to a state (forward movement or stop) other than the rearward movement state in the loaded state, and calculates a load weight of the bucket from a detection value of a work implement sensor (first hydraulic pressure detectors and a first angle detector) based on the determination.

Abstract: The invention relates to a method for calculating the weight of a load moving on scales (1). According to the method, a load signal of the scales is determined over a period of time using the speed of the load, and several partial load signals (TL1, TL2) are used, the total thereof providing the load signal, a first partial load signal (TL1) displaying a maximum value as long as the load is fully on the weighing section of the scales (1), and a second partial load signal (TL2) displaying a minimum value as long as the load is completely removed from the weighing section of the scales (1), and the speed of the movement of the load is determined from said partial load signals (TL1 and TL2). The invention also relates to scales for carrying out said method, comprising two weighing units (10, 11) with flexible deformation elements on which deformation sensors (7, 15), which generate the partial load signals (TL1,TL2), are arranged.

Abstract: A system for measuring and converting food waste is provided. The system includes multiple food waste monitoring devices and a food waste analysis device. These food waste monitoring devices are deployed at different geographical locations. Each of the food waste monitoring devices is configured for obtaining food waste data that includes a reason for waste, a destination of the food waste, and a category of food waste. The food waste data further includes an estimation of the weight of food waste generated by converting the volume of the food waste based on the nature of the food waste. The food waste data is transmitted to the food waste analysis device, which is configured to perform various analysis on the collected food waste data.

Abstract: A scale apparatus is described. The scale apparatus may include a housing sized to fit within a playing card tuck box; a pressure plate operable to measure a weight of a plurality of objects; a wireless transmitter; and a microcontroller in communication with the pressure plate and the wireless transmitter. The microcontroller may be configured to: continuously measure the weight on the pressure plate; when the weight holds steady for a sequence of measurements, transmit a first weight measurement via the wireless transmitter; measure a change in the weight; and when the change in the weight is steady, transmit a second weight measurement via the wireless transmitter.

Abstract: A commercial-transaction weighing instrument (110) subject to W&M legal controls, configured with a weighing platform (12), at least one load cell (16), a controller (120) with weight-processing (122) and communications (124) modules, and software to be implemented on a general-purpose computer with display and data entry capabilities. The general-purpose computer itself is not subject to legal controls. The weight-processing module receives data from the at least one load cell and generates output data in the nature of weight and legally-required weighment information. The communications module receives the output data of the weight-processing module and further transmits the data to a general-purpose computer (136). Software implemented on the general-purpose computer has program code for establishing encrypted bidirectional communication with the communications module and to operate as the primary display device for the weighing instrument.

Abstract: The disclosure provides a material handling method and system. The method includes: obtaining a carrying load of at least two carrying devices on a current production line in a present working period; adjusting a carrying area of at least two carrying devices according to the carrying load, and/or, adjusting the carrying priority level of the sharing carrying sub-area and the independent carrying sub-area of at least two carrying devices according to the carrying load. Each carrying area of one carrying device comprises a sharing carrying sub-area and an independent carrying sub-area.

Abstract: Provided is a weighing apparatus with a flowmeter function includes a load sensor unit configured to detect a load of a flow rate calculation target, an A/D conversion unit configured to sequentially convert load signals from the load sensor unit into digital load data at predetermined intervals, an arithmetic processing unit configured to sequentially convert the load data into weighed values to calculate flow rate values, and a storage unit for storing the weighed values. The arithmetic processing unit calculates change amounts in weighed values and calculates a flow rate value based on a flow rate calculation cycle set based on a minimum time by which the change amounts become equal to or more than a change amount in weighed value, the change amount being calculated based on a minimum indication of weighed value and the required resolution of weighed value and satisfying a required resolution.

Abstract: Methods and systems to prevent relay misoperation and enhance relay dependability during ultrasaturation is disclosed. An ultrasaturation detection system may identify an ultrasaturation condition by comparing a differential current to a first and second derivative of the differential current. When an ultrasaturation condition is determined to be present, the ultrasaturation detection system may provide parameters to a relay to prevent misoperation and enhance relay dependability.

Abstract: A method for determining the weight of an entity/item to be weighed on a weighing device (1), the weighing device comprising at least a weight sensor and a control unit (4), the method comprising the following steps: /a/ collecting weight raw samples (WSi) of the total weight sensed at the weight sensor(s), at a sampling frequency (F0), and converting each of the weight raw samples (WSi) into digitalized weight raw samples (DSi), /b/ entering sequentially each of the digitalized weight raw samples (DSi) into a Butterworth filter, the latter issuing filtered weight samples (FSi), /c/ defining a rolling window (RW) containing a parametrized number NS of latest filtered weight samples (FSi), /d1/ determining, in the rolling window, the minimum (MIN) and maximum (MAX) values of filtered weight samples, /d2/ comparing the value of MAX?MIN with regard to a parametrized Threshold (T), /e/ if MAX?MIN is greater than Threshold (T), repeat steps /a/ to /d2/, and as soon as MAX?MIN is less than Threshold (T), output a

Abstract: A blending system is described for preparing a blended mixture. The blending system includes a control system having at least a processor, a computer-readable memory, and a display, wherein the memory contains software configured to receive a formula defining instructions for preparing a blended mixture using one or more blending materials and amounts recommended for the blended mixture using a scale. The blending system further includes management software stored in the computer-readable memory and executed by the control system, the software in communication with the control system to exchange information on customers and formulas blended mixtures associated with the customers. Additionally, the control system includes software configured to calculate information associated with the blended mixture when an input received by the control system indicates an amount that is different than an amount in the formula and displays the calculated information associated with the blended mixture on the display.

Abstract: Embodiments of the invention generally relate to weighing scale diagnostic methods employing a comparison of like component operating parameters. In certain embodiments, the difference between any two current operating parameter values may be compared against a maximum allowable difference, and/or the deviation of current operating parameters from a calculated measure of central tendency may be determined and compared against a maximum allowable deviation. Alternatively or additionally, a standard statistical test for outliers may be employed. An outlying difference or deviation may be indicative of a problem with the associated component. In other embodiments, the current operating parameters of like components may be compared against calibrated parameters and any deviation of the current parameter for a given component may be compared against the total deviation to determine the percentage of deviation attributable to that component.

Abstract: Apparatus and related methods are provided for automatically recalibrating a SAW scale for changing environmental factors. During a period of time when there is no change to a weight applied to the scale, readings of SAW transducers which relate to weight indications and environmental factor indications are taken for two adjacent operating modes of the scale, and two calibrated weight calculations are made utilizing those readings. The difference in calibrated weight calculations is then related to a variable utilized to transform the readings into weights, which is updated, thereby recalibrating the scale.

Abstract: The method and device are used to adjust a weighing apparatus. A weight indicated by the weighing apparatus is adapted to the gravitation in the area of an installation location of the weighing apparatus. The adaptation is carried out using a code that can be evaluated by the weighing apparatus.

Abstract: In but one embodiment of the present invention, there is provided a system having a display to indicate the amount of a material being added to a scale. The system includes tolerance indication software configured to indicate predefined ranged tolerances above and/or below the recommended amounts, such that a user is able to identify whether the amount added to the scale for a colorant and/or dye blending material is within the predefined ranged tolerances. In yet another aspect the memory includes instructions to recreate formulas based on a specific product brand. Software can be provided to permit a user to convert the formula, either a portion or the entire formula, to a second product brand.

Abstract: This disclosure relates to a system configured to determine masses, weights, and/or other quantities of individual ingredients added to a food dish during preparation. At least some of the components of the system may be configured to be used in a food preparation area. The system may include a scale, a client computing device, external resources, and/or other components. The system may be configured to weigh and/or determine the mass of individual ingredients of the dish as the ingredients are added to the dish. The system may be configured to determine the individual mass and/or weight of each ingredient based on the masses and/or weights of individual ingredients previously added to the dish and/or a current mass and/or weight of the dish as a given ingredient is added.

Abstract: A work vehicle includes one or more leanable wheels, in which the lean angle of each leanable wheel is automatically controlled according to one or more external factors. Factors influencing the lean angle of each leanable wheel may include: draft load arising from externally imposed forces, such as forces arising from moving earthen materials with a vehicle-mounted moldboard; the rotational position of such a moldboard with respect to direction of travel; turning radius of the vehicle during a turning maneuver; engine speed and/or transmission gear; and the angle of the vehicle itself with respect to vertical (i.e., whether the vehicle is on sloped ground). A control system may automatically adjust wheel-lean depending on inputs indicative of any combination of the above-mentioned external factors.

Abstract: A system is provided for determining the current weight of a vehicle and any implement or trailer being towed or carried thereby. The system has an electronic control unit and means to determine the current value of vehicle operating parameters indicative of the current wheel output torque and acceleration of the vehicle. These current parameter values are forwarded to the electronic control unit so that the unit can calculate the current vehicle weight from a predetermined relationship involving wheel output torque, vehicle acceleration and other known current operating parameters of the vehicle. The other known current operating parameters of the vehicle are wheel rolling radius, angle of inclination of the vehicle, gravitational acceleration and rolling resistance of the wheels.

Abstract: A method and apparatus for weighing pharmaceutical product capsules, whereby a capsule containing a pharmaceutical product is fed into a pocket to allow a measuring device to determine the weight of the pharmaceutical product and of a first portion of the capsule containing the pharmaceutical product; the pocket, and therefore the capsule, then being inverted to move the pharmaceutical product out of the first portion and into a second portion of the capsule, to allow the measuring device to determine the weight of the first portion only of the capsule.

Abstract: A commodity search device includes a storage unit, a measuring unit, a number input unit, a unit average weighing value calculator, and a first commodity search unit. The storage unit stores commodity information including a reference unit weight determined for each commodity. The measuring unit measures a total weight of commodities placed at a predetermined weighing position. The number input unit allows inputting the number of the weighed commodities. The unit average weighing value calculator divides the total weight of the commodities weighed by the measuring unit by the number input by the number input unit to calculate a unit average weighing value per one commodity. The first commodity search unit searches for commodities falling within a weight deviation from the storage unit using the unit average weighing value.

Abstract: Apparatus and associated methods relate to a load-cell measurement system having an output that is substantially independent of the system voltage source, by providing compensation for the source voltage variation using both a compensating offset voltage and a compensating reference voltage, these compensating voltages having a predetermined relationship with each other. In an illustrative example, the supply voltage may be directly connected to a load-cell, an instrumentation amplifier, and a compensation circuit. In some examples, the compensation circuit may include a chain of impedances which may generate two mutually related voltages both being scaled to the supply voltage. The first scaled voltage may, for example, substantially compensate offset of the load-cell measurement system. The second scaled voltage may, for example, substantially compensate for gain.

Abstract: A system and method for assisting a user in assembling a culinary combination according to a recipe. The system comprises a scale and a computing device configured to communicate with the scale. The system displays information regarding ingredients of the recipe and displays a progress of assembling the culinary combination based on the information from the scale. In some embodiments, a bar graph is displayed with a bar proportional to the measured amount of an ingredient of the recipe compared to a target amount for the ingredient. In some embodiments, the system displays a build column of one or more recipe blocks, representing actions or ingredients of the recipe. An active recipe block is displayed with a portion of the recipe block displayed in a different manner in proportion to the measured amount of an ingredient of the recipe compared to a target amount for the ingredient.

Abstract: A product container configured to notify or indicate to a user information about a product contained therein. The container has a body defining a volume within for holding the product. A transparent material or light is coupled with the body for permitting a user to determine an amount of the product contained within the body. Markings or other printing may be disposed on or adjacent to the transparent material or light. The container additionally or alternatively has a sensor in communication with a processor for sensing a characteristic of the product. The processor is connected with an indicator coupled to the body for indicating information about the product based upon the sensed characteristic of the product. The processor may interface with a remote device via wired or wireless data transmission.

Abstract: The invention provides a method and a device for measuring the weight of a load, which is displaced with a load lifting device over the edge of a raised loading surface and thus pulled onto the same or pushed down from the same, wherein during this operating process, in a support of the load lifting device loaded by the load, the force currently acting due to the displacement of the load is measured during the passage through a predetermined weighing window and the weight of the load is determined mathematically from the course thereof. Preferably, the load sensor is constructed as a tube which is equipped with two deformation sensors equipped essentially at right angles to one another.

Abstract: A portable electronic device includes a housing, a pressure sensor, a signal processing module, an analog-to-digital converting module, a processor, and a setting keypad. The housing supports an object to be weighed. The pressure sensor is mounted on the housing and outputs an analog voltage signal that varies with a pressure exerted on the pressure sensor. The signal processing module amplifies and filters the analog voltage signal. The analog-to-digital converting module converts the analog voltage signal into a digital signal. The processor calculates a weight exerted on the pressure sensor according to the digital signal and calibrates the weight of the pressure sensor when the setting keypad is activated.

Abstract: A warehouse management system for automatically weighing and counting parts includes a management computer and a weighing device. The management computer communicates with the weighing device. The weighing device includes a base, a tray for carrying a parts bin, and a weighing module. A track is mounted to the base. A roller is mounted on the bottom of the tray and rides on the corresponding track. The tray can move over the track by the roller. The weighing module is attached to one end of the track. The tray together with the parts bin can be actuated to move to the weighing module so as to weigh and count the parts within the parts bin.

Abstract: To provide a weighing apparatus by which it is possible for a user himself/herself to determine poor performance of the apparatus is a factor attributable to an installation environment, and the weighing accuracy is improved. Respective temporal fluctuations in weighed data detected from a load measuring mechanism 2 and environmental measurement data detected in an environmental measurement means 10 are recorded in a correlative manner in an arithmetic processing unit 32, and the temporal fluctuations are visually recognizable via a display unit 31. Thereby, the correlation between the environmental variations and the weighed data is visually disclosed, which makes it possible for a user to easily recognize that poor performance of the apparatus is attributable to the environmental variations, that increases the reliability of the weighing apparatus.

Abstract: A directional tap detection algorithm and a single tri-axis accelerometer are employed to extend the number of unique button less input commands available for a small mobile electronic device. The algorithm analyzes acceleration data from the tri-axis accelerometer to detect the direction and number of taps imparted to any of the six sides of a housing of the device, yielding 12 unique inputs. The algorithm employs a parameter referred to as the performance index (PI) to identify tap induced movements. The PI is determined by calculating the time derivative of each acceleration signal for each axis and then calculating the sum of the absolute values of the calculated acceleration derivatives. A tap is determined to have occurred if the sum exceeds a threshold value for a predetermined amount of time. If a second tap is detected within a predetermined time after the first tap, then a double tap is determined to have occurred.

Abstract: A commodity search device includes a storage unit, a measuring unit, a number input unit, a unit average weighing value calculator, and a first commodity search unit. The storage unit stores commodity information including a reference unit weight determined for each commodity. The measuring unit measures a total weight of commodities placed at a predetermined weighing position. The number input unit allows inputting the number of the weighed commodities. The unit average weighing value calculator divides the total weight of the commodities weighed by the measuring unit by the number input by the number input unit to calculate a unit average weighing value per one commodity. The first commodity search unit searches for commodities falling within a weight deviation from the storage unit using the unit average weighing value.

Abstract: According to one embodiment, a bag supporting table includes a pair of hooking sections configured to support a shopping bag and an auxiliary-bag supporting section. The shopping bag has a pair of grips. The pair of hooking sections are spaced apart from and opposed to each other. The pair of hooking sections respectively hook the grips of the shopping bag and support the shopping bag. The auxiliary-bag supporting section is arranged on the outer side of an arrangement area for the shopping bag supported by the pair of hooking sections.

Abstract: Scale that can measure volume of many foods and ingredients based on density calculations and input of mass from scale. User able to input desired quantity, unit of measurement, and food item by both keypad on unit and or voice recognition. User is then guided to the addition of specified ingredient to targeted amount by visual and auditory indication. The food scale compiles the nutritional information of all used ingredients from programmed nutritional data for the user's knowledge. The food scale is capable of listing ingredient substitutions and storing recipes as well as prompting for additional ingredients in a preprogrammed recipe.

Abstract: The invention regards a portable medical apparatus made up of at least two devices (30, 32) adapted to measure eating rate utilized to teach persons to eat according to a predetermined graphic eating curve (10, 24) displayed on a screen and a method therefore. In a specific mode the predetermined graphic curve (24) describes a non linear descending rate of eating behaviour. The apparatus comprises a device with cellular capabilities (30), and a scale (32), which devices communicate through near field radiation such as Bluetooth or IR.

Abstract: Precision gauge for liquid fuel in a vehicle's tank, based on the usage of electronic scales, a computer, the odometer and an electronic circuit based on the tank weight previous to the loading (Weight 1), density of the used fuel (previously digitized in the computer) and the weight of the tank after loading it (Weight 2); allows visualizing by means of a proper device (digital display), the volume of fuel contained in such tank, VOLUME_=(Weight 2?Weight 1)/DENSITY and eventually to appreciate the amount of fuel consumed by the vehicle per unit of time and/or per kilometer covered.

Abstract: An electronic scale having an integrated computer with an input unit for entering selection data, a memory for storing a plurality of parameter values, which can be assigned to function-specific parameters dependent on the entered selection data, a data processing unit for executing weighing applications dependent on a subset of the function-specific parameters and at least one interface for interacting with mechanical and/or electronic components dependent on a subset of function-specific parameters. A plurality of different profiles (24; 24?) can be stored as individual parameter value sets to adapt to user-specific and/or application-specific requirements. Selecting a specific profile (24; 24?) causes a joint assignment of the values contained therein to the corresponding parameters.

Abstract: A weigh-in-motion device and method having at least one transducer pad, each transducer pad having at least one transducer group with transducers positioned essentially perpendicular to the direction of travel. At least one pad microcomputer is provided on each transducer pad having a means for calculating first output signal indicative of weight, second output signal indicative of time, and third output signal indicative of speed. At least one host microcomputer is in electronic communication with each pad microcomputer, and having a means for calculating at least one unknown selected from the group consisting of individual tire weight, individual axle weight, axle spacing, speed profile, longitudinal center of balance, and transverse center of balance.

Abstract: A weighing apparatus comprises a plurality of load cells and a load platform, supported by the load cells. The apparatus includes means associated with each load cell to supply a digital representation of the load on each load cell. The load cells are connected together to form a communication network. In the network, a digital representation of the load on each load cell is generated, and a correction coefficient of the digital representation for each cell is determined. The correction coefficient is stored in each respective load cell, and again of each load cell is varied according to its correction coefficient to generate a correct digital representation of the load for each load cell.

Abstract: A method of compensating for hysteresis in a load cell, by: (a) pre-calibrating a load cell by: measuring load cell deflection under progressively increasing loads; determining a first set of coefficients correlating the deflection of the load cell to the measured load under the progressively increasing loads; measuring load cell deflection under progressively decreasing loads; determining a second set of coefficients correlating the deflection of the load cell to the measured load under the progressively decreasing loads; and then (b) compensating for hysteresis in the load cell, by: selecting the first set of coefficients if the load on the load cell has been progressively increasing, or selecting the second set of coefficients if the load on the load cell has been progressively decreasing; and applying a formula using the selected first or second set of coefficients to the measured load cell deflection at the particular load, thereby determining an accurate load cell deflection, and thus compensating for h

Abstract: It is an object of the present invention to provide a method of manufacturing a rotor for an electric motor, in which displacement of the center of gravity is prevented. According to a feature of the present invention, a rotor for an electric motor comprises an inner core fixed to a rotating shaft of the rotor and multiple coil units respectively fixed to the inner core, wherein the coil unit has an outer core, a bobbin and a winding wound on the bobbin, and wherein weight of outer cores as well as winding units (the bobbin and the winding wound thereon) is respectively measured and stratified into several groups, necessary number of the outer cores and winding units are respectively picked out from the same stratified group and then such outer cores and winding units are assembled to the inner core.

Abstract: A force-measuring cell is disclosed which is equipped with a force transducer which includes a deformable body that is equipped with sensors. The deformable body connects a housing-mounted fixed part to a force-introducing part of the force transducer. The sensors are connected to electrical conductors of at least one flat ribbon cable which leads to a circuit module that serves to process the measuring signals and contains the connections for joining the sensors together in a measuring bridge circuit. The conductor tracks can be configured so that all of the connecting leads from nodal points of a measuring bridge to the contact terminals of the sensors have at least approximately equal resistance values.

Abstract: A system for weighing a load that uses a weighing apparatus comprising a plurality of load cells (1), a means for receiving a load supported by said load cells, a means associated with each load cell (1) to supply a digital representation of the load on each load cell, said load cells being connected together to form a communication network, wherein a digital representation of the load on each load cell (1) is generated, a correction coefficient Xj of said digital representation for each load cell (1) is determined, said correction coefficient Xj is stored in the respective load cell (1) and the gain of each load cell is varied according to its correction coefficient Xj to generate a correct digital representation of the load for each load cell (1).

Abstract: A method (300) and a system (100) for controlling a casting process are described herein. The system (100) generally includes a die casting device (110) and a measuring device (120). The die casting device (110) includes a mold (130) configured to produce molded parts (140). The measuring device (120) may determine a position of the mold (130) within the die casting device (110) in a casting cycle. The measuring device (120) may determine an incremental increase in weight of molded parts (140) associated with the casting cycle. Based on the incremental increase in weight of molded parts (140), the measuring device (120) may provide a notification in response to a trigger event. The measuring device (120) may also reset the die casting device (110) for another casting cycle based on the incremental increase in weight of molded parts (140).

Abstract: A system for weighing a load that uses a weighing apparatus comprising a plurality of load cells (1), a means for receiving a load supported by said load cells, a means associated with each load cell (1) to supply a digital representation of the load on each load cell, said load cells being connected together to form a communication network, wherein a digital representation of the load on each load cell (1) is generated, a correction coefficient Xj of said digital representation for each load cell (1) is determined, said correction coefficient Xj is stored in the respective load cell (1) and the gain of each load cell is varied according to its correction coefficient Xj to generate a correct digital representation of the load for each load cell (1).

Abstract: In a scale with a weighing cell, which can generate weight signals representing the weight of a load each time something is weighed, and with a signal processing system which receives the weight signals and generates: weight data on the basis of the weight signals, information determined on the basis of the weight data such as purchase prices, and/or weighing data containing identification data designating the weighing operation or group of associated weighing operations in question, an elaboration is proposed, according to which the signal processing system has an encryption unit, which can generate encryption data on the basis of at least some of the weighing data, where the signal processing system can transmit a data record containing at least the portion of the weighing data used to generate the encryption data together with the encryption data.

Abstract: A method and system for determining if a mail piece contains a loose particulate matter is disclosed. The mass of each mail piece is determined twice utilizing a vibrating tray scale. During one determination, the mass of everything contained within the mail piece, including any type of loose particulate matter, is included. During the other determination, the mass of any loose particulate matter contained within the mail piece is not included. If the mail piece contains any type of loose particulate matter, there will be a difference in the masses of the mail piece as determined by the vibrating tray scale, indicating the mail piece may contain a lose particulate matter. The mail piece can then be diverted from the normal processing path for further inspection, thereby preventing cross-contamination of other mail pieces and processing equipment.

Abstract: An apparatus is provided for diagnosing the state of health of a vehicle and for providing the operator of the vehicle with a substantially real-time indication of the efficiency of the vehicle in performing an assigned task with respect to a predetermined goal. A processor on-board the vehicle monitors sensors that provide information regarding the state of health of the vehicle and the amount of work the vehicle has done. In response to anomalies in the data from the sensors, the processor records information that describes events leading up to the occurrence of the anomaly for later analysis that can be used to diagnose the cause of the anomaly. The sensors are also used to prompt the operator of the vehicle to operate the vehicle at optimum efficiency.

Abstract: A platform scale (10) includes a signal processor (22) operable to perform statistical analyzes such as least squares or other mathematical analyzes such as successive approximation of the load signals from the respective load cells (14) supporting a platform (12) in order to produce load position correction factors used in determining the weight of a load on the scale (10).