yoctolib-esm
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Yoctopuce library for TypeScript/JavaScript, as an ECMAScript 2015 module
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JavaScript
/*********************************************************************
*
* $Id: svn_id $
*
* Implements the high-level API for WeighScale functions
*
* - - - - - - - - - License information: - - - - - - - - -
*
* Copyright (C) 2011 and beyond by Yoctopuce Sarl, Switzerland.
*
* Yoctopuce Sarl (hereafter Licensor) grants to you a perpetual
* non-exclusive license to use, modify, copy and integrate this
* file into your software for the sole purpose of interfacing
* with Yoctopuce products.
*
* You may reproduce and distribute copies of this file in
* source or object form, as long as the sole purpose of this
* code is to interface with Yoctopuce products. You must retain
* this notice in the distributed source file.
*
* You should refer to Yoctopuce General Terms and Conditions
* for additional information regarding your rights and
* obligations.
*
* THE SOFTWARE AND DOCUMENTATION ARE PROVIDED 'AS IS' WITHOUT
* WARRANTY OF ANY KIND, EITHER EXPRESS OR IMPLIED, INCLUDING
* WITHOUT LIMITATION, ANY WARRANTY OF MERCHANTABILITY, FITNESS
* FOR A PARTICULAR PURPOSE, TITLE AND NON-INFRINGEMENT. IN NO
* EVENT SHALL LICENSOR BE LIABLE FOR ANY INCIDENTAL, SPECIAL,
* INDIRECT OR CONSEQUENTIAL DAMAGES, LOST PROFITS OR LOST DATA,
* COST OF PROCUREMENT OF SUBSTITUTE GOODS, TECHNOLOGY OR
* SERVICES, ANY CLAIMS BY THIRD PARTIES (INCLUDING BUT NOT
* LIMITED TO ANY DEFENSE THEREOF), ANY CLAIMS FOR INDEMNITY OR
* CONTRIBUTION, OR OTHER SIMILAR COSTS, WHETHER ASSERTED ON THE
* BASIS OF CONTRACT, TORT (INCLUDING NEGLIGENCE), BREACH OF
* WARRANTY, OR OTHERWISE.
*
*********************************************************************/
import { YAPI, YAPIContext, YFunction, YSensor } from './yocto_api.js';
//--- (YWeighScale class start)
/**
* YWeighScale Class: weighing scale sensor control interface, available for instance in the
* Yocto-Bridge or the Yocto-MaxiBridge
*
* The YWeighScale class provides a weight measurement from a ratiometric sensor.
* It can be used to control the bridge excitation parameters, in order to avoid
* measure shifts caused by temperature variation in the electronics, and can also
* automatically apply an additional correction factor based on temperature to
* compensate for offsets in the load cell itself.
*/
//--- (end of YWeighScale class start)
export class YWeighScale extends YSensor {
//--- (end of YWeighScale attributes declaration)
constructor(yapi, func) {
//--- (YWeighScale constructor)
super(yapi, func);
this._excitation = YWeighScale.EXCITATION_INVALID;
this._tempAvgAdaptRatio = YWeighScale.TEMPAVGADAPTRATIO_INVALID;
this._tempChgAdaptRatio = YWeighScale.TEMPCHGADAPTRATIO_INVALID;
this._compTempAvg = YWeighScale.COMPTEMPAVG_INVALID;
this._compTempChg = YWeighScale.COMPTEMPCHG_INVALID;
this._compensation = YWeighScale.COMPENSATION_INVALID;
this._zeroTracking = YWeighScale.ZEROTRACKING_INVALID;
this._command = YWeighScale.COMMAND_INVALID;
this._valueCallbackWeighScale = null;
this._timedReportCallbackWeighScale = null;
// API symbols as object properties
this.EXCITATION_OFF = 0;
this.EXCITATION_DC = 1;
this.EXCITATION_AC = 2;
this.EXCITATION_INVALID = -1;
this.TEMPAVGADAPTRATIO_INVALID = YAPI.INVALID_DOUBLE;
this.TEMPCHGADAPTRATIO_INVALID = YAPI.INVALID_DOUBLE;
this.COMPTEMPAVG_INVALID = YAPI.INVALID_DOUBLE;
this.COMPTEMPCHG_INVALID = YAPI.INVALID_DOUBLE;
this.COMPENSATION_INVALID = YAPI.INVALID_DOUBLE;
this.ZEROTRACKING_INVALID = YAPI.INVALID_DOUBLE;
this.COMMAND_INVALID = YAPI.INVALID_STRING;
this._className = 'WeighScale';
//--- (end of YWeighScale constructor)
}
//--- (YWeighScale implementation)
imm_parseAttr(name, val) {
switch (name) {
case 'excitation':
this._excitation = val;
return 1;
case 'tempAvgAdaptRatio':
this._tempAvgAdaptRatio = Math.round(val / 65.536) / 1000.0;
return 1;
case 'tempChgAdaptRatio':
this._tempChgAdaptRatio = Math.round(val / 65.536) / 1000.0;
return 1;
case 'compTempAvg':
this._compTempAvg = Math.round(val / 65.536) / 1000.0;
return 1;
case 'compTempChg':
this._compTempChg = Math.round(val / 65.536) / 1000.0;
return 1;
case 'compensation':
this._compensation = Math.round(val / 65.536) / 1000.0;
return 1;
case 'zeroTracking':
this._zeroTracking = Math.round(val / 65.536) / 1000.0;
return 1;
case 'command':
this._command = val;
return 1;
}
return super.imm_parseAttr(name, val);
}
/**
* Changes the measuring unit for the weight.
* Remember to call the saveToFlash() method of the module if the
* modification must be kept.
*
* @param newval : a string corresponding to the measuring unit for the weight
*
* @return YAPI.SUCCESS if the call succeeds.
*
* On failure, throws an exception or returns a negative error code.
*/
async set_unit(newval) {
let rest_val;
rest_val = String(newval);
return await this._setAttr('unit', rest_val);
}
/**
* Returns the current load cell bridge excitation method.
*
* @return a value among YWeighScale.EXCITATION_OFF, YWeighScale.EXCITATION_DC and
* YWeighScale.EXCITATION_AC corresponding to the current load cell bridge excitation method
*
* On failure, throws an exception or returns YWeighScale.EXCITATION_INVALID.
*/
async get_excitation() {
let res;
if (this._cacheExpiration <= this._yapi.GetTickCount()) {
if (await this.load(this._yapi.defaultCacheValidity) != this._yapi.SUCCESS) {
return YWeighScale.EXCITATION_INVALID;
}
}
res = this._excitation;
return res;
}
/**
* Changes the current load cell bridge excitation method.
* Remember to call the saveToFlash() method of the module if the
* modification must be kept.
*
* @param newval : a value among YWeighScale.EXCITATION_OFF, YWeighScale.EXCITATION_DC and
* YWeighScale.EXCITATION_AC corresponding to the current load cell bridge excitation method
*
* @return YAPI.SUCCESS if the call succeeds.
*
* On failure, throws an exception or returns a negative error code.
*/
async set_excitation(newval) {
let rest_val;
rest_val = String(newval);
return await this._setAttr('excitation', rest_val);
}
/**
* Changes the averaged temperature update rate, in per mille.
* The purpose of this adaptation ratio is to model the thermal inertia of the load cell.
* The averaged temperature is updated every 10 seconds, by applying this adaptation rate
* to the difference between the measures ambient temperature and the current compensation
* temperature. The standard rate is 0.2 per mille, and the maximal rate is 65 per mille.
* Remember to call the saveToFlash() method of the module if the
* modification must be kept.
*
* @param newval : a floating point number corresponding to the averaged temperature update rate, in per mille
*
* @return YAPI.SUCCESS if the call succeeds.
*
* On failure, throws an exception or returns a negative error code.
*/
async set_tempAvgAdaptRatio(newval) {
let rest_val;
rest_val = String(Math.round(newval * 65536.0));
return await this._setAttr('tempAvgAdaptRatio', rest_val);
}
/**
* Returns the averaged temperature update rate, in per mille.
* The purpose of this adaptation ratio is to model the thermal inertia of the load cell.
* The averaged temperature is updated every 10 seconds, by applying this adaptation rate
* to the difference between the measures ambient temperature and the current compensation
* temperature. The standard rate is 0.2 per mille, and the maximal rate is 65 per mille.
*
* @return a floating point number corresponding to the averaged temperature update rate, in per mille
*
* On failure, throws an exception or returns YWeighScale.TEMPAVGADAPTRATIO_INVALID.
*/
async get_tempAvgAdaptRatio() {
let res;
if (this._cacheExpiration <= this._yapi.GetTickCount()) {
if (await this.load(this._yapi.defaultCacheValidity) != this._yapi.SUCCESS) {
return YWeighScale.TEMPAVGADAPTRATIO_INVALID;
}
}
res = this._tempAvgAdaptRatio;
return res;
}
/**
* Changes the temperature change update rate, in per mille.
* The temperature change is updated every 10 seconds, by applying this adaptation rate
* to the difference between the measures ambient temperature and the current temperature used for
* change compensation. The standard rate is 0.6 per mille, and the maximal rate is 65 per mille.
* Remember to call the saveToFlash() method of the module if the
* modification must be kept.
*
* @param newval : a floating point number corresponding to the temperature change update rate, in per mille
*
* @return YAPI.SUCCESS if the call succeeds.
*
* On failure, throws an exception or returns a negative error code.
*/
async set_tempChgAdaptRatio(newval) {
let rest_val;
rest_val = String(Math.round(newval * 65536.0));
return await this._setAttr('tempChgAdaptRatio', rest_val);
}
/**
* Returns the temperature change update rate, in per mille.
* The temperature change is updated every 10 seconds, by applying this adaptation rate
* to the difference between the measures ambient temperature and the current temperature used for
* change compensation. The standard rate is 0.6 per mille, and the maximal rate is 65 per mille.
*
* @return a floating point number corresponding to the temperature change update rate, in per mille
*
* On failure, throws an exception or returns YWeighScale.TEMPCHGADAPTRATIO_INVALID.
*/
async get_tempChgAdaptRatio() {
let res;
if (this._cacheExpiration <= this._yapi.GetTickCount()) {
if (await this.load(this._yapi.defaultCacheValidity) != this._yapi.SUCCESS) {
return YWeighScale.TEMPCHGADAPTRATIO_INVALID;
}
}
res = this._tempChgAdaptRatio;
return res;
}
/**
* Returns the current averaged temperature, used for thermal compensation.
*
* @return a floating point number corresponding to the current averaged temperature, used for thermal compensation
*
* On failure, throws an exception or returns YWeighScale.COMPTEMPAVG_INVALID.
*/
async get_compTempAvg() {
let res;
if (this._cacheExpiration <= this._yapi.GetTickCount()) {
if (await this.load(this._yapi.defaultCacheValidity) != this._yapi.SUCCESS) {
return YWeighScale.COMPTEMPAVG_INVALID;
}
}
res = this._compTempAvg;
return res;
}
/**
* Returns the current temperature variation, used for thermal compensation.
*
* @return a floating point number corresponding to the current temperature variation, used for
* thermal compensation
*
* On failure, throws an exception or returns YWeighScale.COMPTEMPCHG_INVALID.
*/
async get_compTempChg() {
let res;
if (this._cacheExpiration <= this._yapi.GetTickCount()) {
if (await this.load(this._yapi.defaultCacheValidity) != this._yapi.SUCCESS) {
return YWeighScale.COMPTEMPCHG_INVALID;
}
}
res = this._compTempChg;
return res;
}
/**
* Returns the current current thermal compensation value.
*
* @return a floating point number corresponding to the current current thermal compensation value
*
* On failure, throws an exception or returns YWeighScale.COMPENSATION_INVALID.
*/
async get_compensation() {
let res;
if (this._cacheExpiration <= this._yapi.GetTickCount()) {
if (await this.load(this._yapi.defaultCacheValidity) != this._yapi.SUCCESS) {
return YWeighScale.COMPENSATION_INVALID;
}
}
res = this._compensation;
return res;
}
/**
* Changes the zero tracking threshold value. When this threshold is larger than
* zero, any measure under the threshold will automatically be ignored and the
* zero compensation will be updated.
* Remember to call the saveToFlash() method of the module if the
* modification must be kept.
*
* @param newval : a floating point number corresponding to the zero tracking threshold value
*
* @return YAPI.SUCCESS if the call succeeds.
*
* On failure, throws an exception or returns a negative error code.
*/
async set_zeroTracking(newval) {
let rest_val;
rest_val = String(Math.round(newval * 65536.0));
return await this._setAttr('zeroTracking', rest_val);
}
/**
* Returns the zero tracking threshold value. When this threshold is larger than
* zero, any measure under the threshold will automatically be ignored and the
* zero compensation will be updated.
*
* @return a floating point number corresponding to the zero tracking threshold value
*
* On failure, throws an exception or returns YWeighScale.ZEROTRACKING_INVALID.
*/
async get_zeroTracking() {
let res;
if (this._cacheExpiration <= this._yapi.GetTickCount()) {
if (await this.load(this._yapi.defaultCacheValidity) != this._yapi.SUCCESS) {
return YWeighScale.ZEROTRACKING_INVALID;
}
}
res = this._zeroTracking;
return res;
}
async get_command() {
let res;
if (this._cacheExpiration <= this._yapi.GetTickCount()) {
if (await this.load(this._yapi.defaultCacheValidity) != this._yapi.SUCCESS) {
return YWeighScale.COMMAND_INVALID;
}
}
res = this._command;
return res;
}
async set_command(newval) {
let rest_val;
rest_val = String(newval);
return await this._setAttr('command', rest_val);
}
/**
* Retrieves a weighing scale sensor for a given identifier.
* The identifier can be specified using several formats:
*
* - FunctionLogicalName
* - ModuleSerialNumber.FunctionIdentifier
* - ModuleSerialNumber.FunctionLogicalName
* - ModuleLogicalName.FunctionIdentifier
* - ModuleLogicalName.FunctionLogicalName
*
*
* This function does not require that the weighing scale sensor is online at the time
* it is invoked. The returned object is nevertheless valid.
* Use the method YWeighScale.isOnline() to test if the weighing scale sensor is
* indeed online at a given time. In case of ambiguity when looking for
* a weighing scale sensor by logical name, no error is notified: the first instance
* found is returned. The search is performed first by hardware name,
* then by logical name.
*
* If a call to this object's is_online() method returns FALSE although
* you are certain that the matching device is plugged, make sure that you did
* call registerHub() at application initialization time.
*
* @param func : a string that uniquely characterizes the weighing scale sensor, for instance
* YWBRIDG1.weighScale1.
*
* @return a YWeighScale object allowing you to drive the weighing scale sensor.
*/
static FindWeighScale(func) {
let obj;
obj = YFunction._FindFromCache('WeighScale', func);
if (obj == null) {
obj = new YWeighScale(YAPI, func);
YFunction._AddToCache('WeighScale', func, obj);
}
return obj;
}
/**
* Retrieves a weighing scale sensor for a given identifier in a YAPI context.
* The identifier can be specified using several formats:
*
* - FunctionLogicalName
* - ModuleSerialNumber.FunctionIdentifier
* - ModuleSerialNumber.FunctionLogicalName
* - ModuleLogicalName.FunctionIdentifier
* - ModuleLogicalName.FunctionLogicalName
*
*
* This function does not require that the weighing scale sensor is online at the time
* it is invoked. The returned object is nevertheless valid.
* Use the method YWeighScale.isOnline() to test if the weighing scale sensor is
* indeed online at a given time. In case of ambiguity when looking for
* a weighing scale sensor by logical name, no error is notified: the first instance
* found is returned. The search is performed first by hardware name,
* then by logical name.
*
* @param yctx : a YAPI context
* @param func : a string that uniquely characterizes the weighing scale sensor, for instance
* YWBRIDG1.weighScale1.
*
* @return a YWeighScale object allowing you to drive the weighing scale sensor.
*/
static FindWeighScaleInContext(yctx, func) {
let obj;
obj = YFunction._FindFromCacheInContext(yctx, 'WeighScale', func);
if (obj == null) {
obj = new YWeighScale(yctx, func);
YFunction._AddToCache('WeighScale', func, obj);
}
return obj;
}
/**
* Registers the callback function that is invoked on every change of advertised value.
* The callback is then invoked only during the execution of ySleep or yHandleEvents.
* This provides control over the time when the callback is triggered. For good responsiveness,
* remember to call one of these two functions periodically. The callback is called once juste after beeing
* registered, passing the current advertised value of the function, provided that it is not an empty string.
* To unregister a callback, pass a null pointer as argument.
*
* @param callback : the callback function to call, or a null pointer. The callback function should take two
* arguments: the function object of which the value has changed, and the character string describing
* the new advertised value.
* @noreturn
*/
async registerValueCallback(callback) {
let val;
if (callback != null) {
await YFunction._UpdateValueCallbackList(this, true);
}
else {
await YFunction._UpdateValueCallbackList(this, false);
}
this._valueCallbackWeighScale = callback;
// Immediately invoke value callback with current value
if (callback != null && await this.isOnline()) {
val = this._advertisedValue;
if (!(val == '')) {
await this._invokeValueCallback(val);
}
}
return 0;
}
async _invokeValueCallback(value) {
if (this._valueCallbackWeighScale != null) {
try {
await this._valueCallbackWeighScale(this, value);
}
catch (e) {
this._yapi.imm_log('Exception in valueCallback:', e);
}
}
else {
await super._invokeValueCallback(value);
}
return 0;
}
/**
* Registers the callback function that is invoked on every periodic timed notification.
* The callback is invoked only during the execution of ySleep or yHandleEvents.
* This provides control over the time when the callback is triggered. For good responsiveness, remember to call
* one of these two functions periodically. To unregister a callback, pass a null pointer as argument.
*
* @param callback : the callback function to call, or a null pointer. The callback function should take two
* arguments: the function object of which the value has changed, and an YMeasure object describing
* the new advertised value.
* @noreturn
*/
async registerTimedReportCallback(callback) {
let sensor;
sensor = this;
if (callback != null) {
await YFunction._UpdateTimedReportCallbackList(sensor, true);
}
else {
await YFunction._UpdateTimedReportCallbackList(sensor, false);
}
this._timedReportCallbackWeighScale = callback;
return 0;
}
async _invokeTimedReportCallback(value) {
if (this._timedReportCallbackWeighScale != null) {
try {
await this._timedReportCallbackWeighScale(this, value);
}
catch (e) {
this._yapi.imm_log('Exception in timedReportCallback:', e);
}
}
else {
await super._invokeTimedReportCallback(value);
}
return 0;
}
/**
* Adapts the load cell signal bias (stored in the corresponding genericSensor)
* so that the current signal corresponds to a zero weight. Remember to call the
* saveToFlash() method of the module if the modification must be kept.
*
* @return YAPI.SUCCESS if the call succeeds.
*
* On failure, throws an exception or returns a negative error code.
*/
async tare() {
return await this.set_command('T');
}
/**
* Configures the load cell span parameters (stored in the corresponding genericSensor)
* so that the current signal corresponds to the specified reference weight.
*
* @param currWeight : reference weight presently on the load cell.
* @param maxWeight : maximum weight to be expected on the load cell.
*
* @return YAPI.SUCCESS if the call succeeds.
*
* On failure, throws an exception or returns a negative error code.
*/
async setupSpan(currWeight, maxWeight) {
return await this.set_command('S' + String(Math.round(Math.round(1000 * currWeight))) + ':' + String(Math.round(Math.round(1000 * maxWeight))));
}
async setCompensationTable(tableIndex, tempValues, compValues) {
let siz;
let res;
let idx;
let found;
let prev;
let curr;
let currComp;
let idxTemp;
siz = tempValues.length;
if (!(siz != 1)) {
return this._throw(this._yapi.INVALID_ARGUMENT, 'thermal compensation table must have at least two points', this._yapi.INVALID_ARGUMENT);
}
if (!(siz == compValues.length)) {
return this._throw(this._yapi.INVALID_ARGUMENT, 'table sizes mismatch', this._yapi.INVALID_ARGUMENT);
}
res = await this.set_command(String(Math.round(tableIndex)) + 'Z');
if (!(res == this._yapi.SUCCESS)) {
return this._throw(this._yapi.IO_ERROR, 'unable to reset thermal compensation table', this._yapi.IO_ERROR);
}
// add records in growing temperature value
found = 1;
prev = -999999.0;
while (found > 0) {
found = 0;
curr = 99999999.0;
currComp = -999999.0;
idx = 0;
while (idx < siz) {
idxTemp = tempValues[idx];
if ((idxTemp > prev) && (idxTemp < curr)) {
curr = idxTemp;
currComp = compValues[idx];
found = 1;
}
idx = idx + 1;
}
if (found > 0) {
res = await this.set_command(String(Math.round(tableIndex)) + 'm' + String(Math.round(Math.round(1000 * curr))) + ':' + String(Math.round(Math.round(1000 * currComp))));
if (!(res == this._yapi.SUCCESS)) {
return this._throw(this._yapi.IO_ERROR, 'unable to set thermal compensation table', this._yapi.IO_ERROR);
}
prev = curr;
}
}
return this._yapi.SUCCESS;
}
async loadCompensationTable(tableIndex, tempValues, compValues) {
let id;
let bin_json;
let paramlist = [];
let siz;
let idx;
let temp;
let comp;
id = await this.get_functionId();
id = id.substr(10, (id).length - 10);
bin_json = await this._download('extra.json?page=' + String(Math.round((4 * YAPIContext.imm_atoi(id)) + tableIndex)));
paramlist = this.imm_json_get_array(bin_json);
// convert all values to float and append records
siz = (paramlist.length >> 1);
tempValues.length = 0;
compValues.length = 0;
idx = 0;
while (idx < siz) {
temp = YAPIContext.imm_atof(this._yapi.imm_bin2str(paramlist[2 * idx])) / 1000.0;
comp = YAPIContext.imm_atof(this._yapi.imm_bin2str(paramlist[2 * idx + 1])) / 1000.0;
tempValues.push(temp);
compValues.push(comp);
idx = idx + 1;
}
return this._yapi.SUCCESS;
}
/**
* Records a weight offset thermal compensation table, in order to automatically correct the
* measured weight based on the averaged compensation temperature.
* The weight correction will be applied by linear interpolation between specified points.
*
* @param tempValues : array of floating point numbers, corresponding to all averaged
* temperatures for which an offset correction is specified.
* @param compValues : array of floating point numbers, corresponding to the offset correction
* to apply for each of the temperature included in the first
* argument, index by index.
*
* @return YAPI.SUCCESS if the call succeeds.
*
* On failure, throws an exception or returns a negative error code.
*/
async set_offsetAvgCompensationTable(tempValues, compValues) {
return await this.setCompensationTable(0, tempValues, compValues);
}
/**
* Retrieves the weight offset thermal compensation table previously configured using the
* set_offsetAvgCompensationTable function.
* The weight correction is applied by linear interpolation between specified points.
*
* @param tempValues : array of floating point numbers, that is filled by the function
* with all averaged temperatures for which an offset correction is specified.
* @param compValues : array of floating point numbers, that is filled by the function
* with the offset correction applied for each of the temperature
* included in the first argument, index by index.
*
* @return YAPI.SUCCESS if the call succeeds.
*
* On failure, throws an exception or returns a negative error code.
*/
async loadOffsetAvgCompensationTable(tempValues, compValues) {
return await this.loadCompensationTable(0, tempValues, compValues);
}
/**
* Records a weight offset thermal compensation table, in order to automatically correct the
* measured weight based on the variation of temperature.
* The weight correction will be applied by linear interpolation between specified points.
*
* @param tempValues : array of floating point numbers, corresponding to temperature
* variations for which an offset correction is specified.
* @param compValues : array of floating point numbers, corresponding to the offset correction
* to apply for each of the temperature variation included in the first
* argument, index by index.
*
* @return YAPI.SUCCESS if the call succeeds.
*
* On failure, throws an exception or returns a negative error code.
*/
async set_offsetChgCompensationTable(tempValues, compValues) {
return await this.setCompensationTable(1, tempValues, compValues);
}
/**
* Retrieves the weight offset thermal compensation table previously configured using the
* set_offsetChgCompensationTable function.
* The weight correction is applied by linear interpolation between specified points.
*
* @param tempValues : array of floating point numbers, that is filled by the function
* with all temperature variations for which an offset correction is specified.
* @param compValues : array of floating point numbers, that is filled by the function
* with the offset correction applied for each of the temperature
* variation included in the first argument, index by index.
*
* @return YAPI.SUCCESS if the call succeeds.
*
* On failure, throws an exception or returns a negative error code.
*/
async loadOffsetChgCompensationTable(tempValues, compValues) {
return await this.loadCompensationTable(1, tempValues, compValues);
}
/**
* Records a weight span thermal compensation table, in order to automatically correct the
* measured weight based on the compensation temperature.
* The weight correction will be applied by linear interpolation between specified points.
*
* @param tempValues : array of floating point numbers, corresponding to all averaged
* temperatures for which a span correction is specified.
* @param compValues : array of floating point numbers, corresponding to the span correction
* (in percents) to apply for each of the temperature included in the first
* argument, index by index.
*
* @return YAPI.SUCCESS if the call succeeds.
*
* On failure, throws an exception or returns a negative error code.
*/
async set_spanAvgCompensationTable(tempValues, compValues) {
return await this.setCompensationTable(2, tempValues, compValues);
}
/**
* Retrieves the weight span thermal compensation table previously configured using the
* set_spanAvgCompensationTable function.
* The weight correction is applied by linear interpolation between specified points.
*
* @param tempValues : array of floating point numbers, that is filled by the function
* with all averaged temperatures for which an span correction is specified.
* @param compValues : array of floating point numbers, that is filled by the function
* with the span correction applied for each of the temperature
* included in the first argument, index by index.
*
* @return YAPI.SUCCESS if the call succeeds.
*
* On failure, throws an exception or returns a negative error code.
*/
async loadSpanAvgCompensationTable(tempValues, compValues) {
return await this.loadCompensationTable(2, tempValues, compValues);
}
/**
* Records a weight span thermal compensation table, in order to automatically correct the
* measured weight based on the variation of temperature.
* The weight correction will be applied by linear interpolation between specified points.
*
* @param tempValues : array of floating point numbers, corresponding to all variations of
* temperatures for which a span correction is specified.
* @param compValues : array of floating point numbers, corresponding to the span correction
* (in percents) to apply for each of the temperature variation included
* in the first argument, index by index.
*
* @return YAPI.SUCCESS if the call succeeds.
*
* On failure, throws an exception or returns a negative error code.
*/
async set_spanChgCompensationTable(tempValues, compValues) {
return await this.setCompensationTable(3, tempValues, compValues);
}
/**
* Retrieves the weight span thermal compensation table previously configured using the
* set_spanChgCompensationTable function.
* The weight correction is applied by linear interpolation between specified points.
*
* @param tempValues : array of floating point numbers, that is filled by the function
* with all variation of temperature for which an span correction is specified.
* @param compValues : array of floating point numbers, that is filled by the function
* with the span correction applied for each of variation of temperature
* included in the first argument, index by index.
*
* @return YAPI.SUCCESS if the call succeeds.
*
* On failure, throws an exception or returns a negative error code.
*/
async loadSpanChgCompensationTable(tempValues, compValues) {
return await this.loadCompensationTable(3, tempValues, compValues);
}
/**
* Continues the enumeration of weighing scale sensors started using yFirstWeighScale().
* Caution: You can't make any assumption about the returned weighing scale sensors order.
* If you want to find a specific a weighing scale sensor, use WeighScale.findWeighScale()
* and a hardwareID or a logical name.
*
* @return a pointer to a YWeighScale object, corresponding to
* a weighing scale sensor currently online, or a null pointer
* if there are no more weighing scale sensors to enumerate.
*/
nextWeighScale() {
let resolve = this._yapi.imm_resolveFunction(this._className, this._func);
if (resolve.errorType != YAPI.SUCCESS)
return null;
let next_hwid = this._yapi.imm_getNextHardwareId(this._className, resolve.result);
if (next_hwid == null)
return null;
return YWeighScale.FindWeighScaleInContext(this._yapi, next_hwid);
}
/**
* Starts the enumeration of weighing scale sensors currently accessible.
* Use the method YWeighScale.nextWeighScale() to iterate on
* next weighing scale sensors.
*
* @return a pointer to a YWeighScale object, corresponding to
* the first weighing scale sensor currently online, or a null pointer
* if there are none.
*/
static FirstWeighScale() {
let next_hwid = YAPI.imm_getFirstHardwareId('WeighScale');
if (next_hwid == null)
return null;
return YWeighScale.FindWeighScale(next_hwid);
}
/**
* Starts the enumeration of weighing scale sensors currently accessible.
* Use the method YWeighScale.nextWeighScale() to iterate on
* next weighing scale sensors.
*
* @param yctx : a YAPI context.
*
* @return a pointer to a YWeighScale object, corresponding to
* the first weighing scale sensor currently online, or a null pointer
* if there are none.
*/
static FirstWeighScaleInContext(yctx) {
let next_hwid = yctx.imm_getFirstHardwareId('WeighScale');
if (next_hwid == null)
return null;
return YWeighScale.FindWeighScaleInContext(yctx, next_hwid);
}
}
// API symbols as static members
YWeighScale.EXCITATION_OFF = 0;
YWeighScale.EXCITATION_DC = 1;
YWeighScale.EXCITATION_AC = 2;
YWeighScale.EXCITATION_INVALID = -1;
YWeighScale.TEMPAVGADAPTRATIO_INVALID = YAPI.INVALID_DOUBLE;
YWeighScale.TEMPCHGADAPTRATIO_INVALID = YAPI.INVALID_DOUBLE;
YWeighScale.COMPTEMPAVG_INVALID = YAPI.INVALID_DOUBLE;
YWeighScale.COMPTEMPCHG_INVALID = YAPI.INVALID_DOUBLE;
YWeighScale.COMPENSATION_INVALID = YAPI.INVALID_DOUBLE;
YWeighScale.ZEROTRACKING_INVALID = YAPI.INVALID_DOUBLE;
YWeighScale.COMMAND_INVALID = YAPI.INVALID_STRING;
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