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Author SHA1 Message Date
znetsixe
7eafd89f4e docs: add CLAUDE.md with S88 classification and superproject rule reference 
References the flow-layout rule set in the EVOLV superproject
(.claude/rules/node-red-flow-layout.md) so Claude Code sessions working
in this repo know the S88 level, colour, and placement lane for this node.

Co-Authored-By: Claude Opus 4.6 (1M context) <noreply@anthropic.com>
 2026-04-14 07:47:23 +02:00
znetsixe
d55f401ab3 fix: production hardening — unit mismatch, safety guards, marginal-cost refinement 
- Fix flowmovement unit mismatch: MGC computed flow in canonical (m³/s)
  but rotatingMachine expects output units (m³/h). All flowmovement calls
  now convert via _canonicalToOutputFlow(). Without this fix, every pump
  stayed at minimum flow regardless of demand.
- Fix absolute scaling: demandQout vs demandQ comparison bug, reorder
  conditions so <= 0 is checked first, add else branch for valid demand.
- Fix empty Qd <= 0 block: now calls turnOffAllMachines().
- Add empty-machines guards on optimalControl and equalizePressure.
- Add null fallback (|| 0) on pressure measurement reads.
- Fix division-by-zero in calcRelativeDistanceFromPeak.
- Fix missing flowmovement after startup in equalFlowControl.
- Add marginal-cost refinement loop in BEP-Gravitation: after slope-based
  redistribution, iteratively shifts flow from highest actual dP/dQ to
  lowest using real power evaluations. Closes gap to brute-force optimum
  from 2.1% to <0.1% without affecting combination selection stability.
- Add NCog distribution comparison tests and brute-force power table test.

Co-Authored-By: Claude Opus 4.6 (1M context) <noreply@anthropic.com>
 2026-04-07 13:40:45 +02:00
znetsixe
ffb2072baa Merge commit '85797b5' into HEAD 
# Conflicts:
#	src/nodeClass.js
#	src/specificClass.js
 2026-03-31 18:17:41 +02:00
Rene De Ren
85797b5b8b Align machineGroupControl with current architecture 2026-03-12 16:43:29 +01:00
znetsixe
b337bf9eb7 updates 2026-03-11 11:12:52 +01:00
znetsixe
f8012c8bad update 2026-02-23 13:17:39 +01:00
znetsixe
ee38c8b581 before functional changes by codex 2026-02-19 17:38:05 +01:00
19 changed files with 1215 additions and 227 deletions
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23
CLAUDE.md Normal file
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@@ -0,0 +1,23 @@
# machineGroupControl — Claude Code context
Coordinates multiple rotatingMachine or valve children.
Part of the [EVOLV](https://gitea.wbd-rd.nl/RnD/EVOLV) wastewater-automation platform.
## S88 classification
| Level | Colour | Placement lane |
|---|---|---|
| **Unit** | `#50a8d9` | L4 |
## Flow layout rules
When wiring this node into a multi-node demo or production flow, follow the
placement rule set in the **EVOLV superproject**:
> `.claude/rules/node-red-flow-layout.md` (in the EVOLV repo root)
Key points for this node:
- Place on lane **L4** (x-position per the lane table in the rule).
- Stack same-level siblings vertically.
- Parent/children sit on adjacent lanes (children one lane left, parent one lane right).
- Wrap in a Node-RED group box coloured `#50a8d9` (Unit).

8
examples/README.md Normal file
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@@ -0,0 +1,8 @@
# machineGroupControl Example Flows
Import-ready Node-RED examples for machineGroupControl.
## Files
- basic.flow.json
- integration.flow.json
- edge.flow.json

6
examples/basic.flow.json Normal file
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@@ -0,0 +1,6 @@
[
{"id":"machineGroupControl_basic_tab","type":"tab","label":"machineGroupControl basic","disabled":false,"info":"machineGroupControl basic example"},
{"id":"machineGroupControl_basic_node","type":"machineGroupControl","z":"machineGroupControl_basic_tab","name":"machineGroupControl basic","x":420,"y":180,"wires":[["machineGroupControl_basic_dbg"]]},
{"id":"machineGroupControl_basic_inj","type":"inject","z":"machineGroupControl_basic_tab","name":"basic trigger","props":[{"p":"topic","vt":"str"},{"p":"payload","vt":"str"}],"topic":"ping","payload":"1","payloadType":"str","x":160,"y":180,"wires":[["machineGroupControl_basic_node"]]},
{"id":"machineGroupControl_basic_dbg","type":"debug","z":"machineGroupControl_basic_tab","name":"machineGroupControl basic debug","active":true,"tosidebar":true,"console":false,"tostatus":false,"complete":"true","targetType":"full","x":660,"y":180,"wires":[]}
]

6
examples/edge.flow.json Normal file
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@@ -0,0 +1,6 @@
[
{"id":"machineGroupControl_edge_tab","type":"tab","label":"machineGroupControl edge","disabled":false,"info":"machineGroupControl edge example"},
{"id":"machineGroupControl_edge_node","type":"machineGroupControl","z":"machineGroupControl_edge_tab","name":"machineGroupControl edge","x":420,"y":180,"wires":[["machineGroupControl_edge_dbg"]]},
{"id":"machineGroupControl_edge_inj","type":"inject","z":"machineGroupControl_edge_tab","name":"unknown topic","props":[{"p":"topic","vt":"str"},{"p":"payload","vt":"str"}],"topic":"doesNotExist","payload":"x","payloadType":"str","x":170,"y":180,"wires":[["machineGroupControl_edge_node"]]},
{"id":"machineGroupControl_edge_dbg","type":"debug","z":"machineGroupControl_edge_tab","name":"machineGroupControl edge debug","active":true,"tosidebar":true,"console":false,"tostatus":false,"complete":"true","targetType":"full","x":660,"y":180,"wires":[]}
]

6
examples/integration.flow.json Normal file
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@@ -0,0 +1,6 @@
[
{"id":"machineGroupControl_int_tab","type":"tab","label":"machineGroupControl integration","disabled":false,"info":"machineGroupControl integration example"},
{"id":"machineGroupControl_int_node","type":"machineGroupControl","z":"machineGroupControl_int_tab","name":"machineGroupControl integration","x":420,"y":180,"wires":[["machineGroupControl_int_dbg"]]},
{"id":"machineGroupControl_int_inj","type":"inject","z":"machineGroupControl_int_tab","name":"registerChild","props":[{"p":"topic","vt":"str"},{"p":"payload","vt":"str"}],"topic":"registerChild","payload":"example-child-id","payloadType":"str","x":170,"y":180,"wires":[["machineGroupControl_int_node"]]},
{"id":"machineGroupControl_int_dbg","type":"debug","z":"machineGroupControl_int_tab","name":"machineGroupControl integration debug","active":true,"tosidebar":true,"console":false,"tostatus":false,"complete":"true","targetType":"full","x":680,"y":180,"wires":[]}
]

22
mgc.html
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@@ -18,6 +18,8 @@
defaults: {
// Define default properties
name: { value: "" },
processOutputFormat: { value: "process" },
dbaseOutputFormat: { value: "influxdb" },
// Logger properties
enableLog: { value: false },
@@ -39,7 +41,7 @@
icon: "font-awesome/fa-cogs",
label: function () {
return this.positionIcon + " " + "machineGroup";
return (this.positionIcon || "") + " machineGroup";
},
oneditprepare: function() {
// Initialize the menu data for the node
@@ -74,6 +76,24 @@
<script type="text/html" data-template-name="machineGroupControl">
<h3>Output Formats</h3>
<div class="form-row">
<label for="node-input-processOutputFormat"><i class="fa fa-random"></i> Process Output</label>
<select id="node-input-processOutputFormat" style="width:60%;">
<option value="process">process</option>
<option value="json">json</option>
<option value="csv">csv</option>
</select>
</div>
<div class="form-row">
<label for="node-input-dbaseOutputFormat"><i class="fa fa-database"></i> Database Output</label>
<select id="node-input-dbaseOutputFormat" style="width:60%;">
<option value="influxdb">influxdb</option>
<option value="json">json</option>
<option value="csv">csv</option>
</select>
</div>
<!-- Logger fields injected here -->
<div id="logger-fields-placeholder"></div>

2
package.json
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@@ -4,7 +4,7 @@
"description": "Control module machineGroupControl",
"main": "mgc.js",
"scripts": {
"test": "node mgc.js"
"test": "node --test test/basic/*.test.js test/integration/*.test.js test/edge/*.test.js"
},
"repository": {
"type": "git",

111
src/nodeClass.js
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@@ -1,4 +1,4 @@
const { outputUtils, configManager } = require("generalFunctions");
const { outputUtils, configManager, convert } = require("generalFunctions");
const Specific = require("./specificClass");
class nodeClass {
@@ -37,26 +37,33 @@ class nodeClass {
_loadConfig(uiConfig, node) {
const cfgMgr = new configManager();
this.defaultConfig = cfgMgr.getConfig(this.name);
const flowUnit = this._resolveUnitOrFallback(uiConfig.unit, 'volumeFlowRate', 'm3/h', 'flow');
// Build config: base sections (no domain-specific config for group controller)
this.config = cfgMgr.buildConfig(this.name, uiConfig, node.id);
// Merge UI config over defaults
this.config = {
general: {
name: uiConfig.name,
id: node.id, // node.id is for the child registration process
unit: uiConfig.unit, // add converter options later to convert to default units (need like a model that defines this which units we are going to use and then conver to those standards)
logging: {
enabled: uiConfig.enableLog,
logLevel: uiConfig.logLevel,
},
},
functionality: {
positionVsParent: uiConfig.positionVsParent || "atEquipment", // Default to 'atEquipment' if not set
},
};
// Utility for formatting outputs
this._output = new outputUtils();
}
_resolveUnitOrFallback(candidate, expectedMeasure, fallbackUnit, label) {
const raw = typeof candidate === "string" ? candidate.trim() : "";
const fallback = String(fallbackUnit || "").trim();
if (!raw) {
return fallback;
}
try {
const desc = convert().describe(raw);
if (expectedMeasure && desc.measure !== expectedMeasure) {
throw new Error(`expected '${expectedMeasure}' but got '${desc.measure}'`);
}
return raw;
} catch (error) {
this.node?.warn?.(`Invalid ${label} unit '${raw}' (${error.message}). Falling back to '${fallback}'.`);
return fallback;
}
}
_updateNodeStatus() {
//console.log('Updating node status...');
const mg = this.source;
@@ -68,19 +75,19 @@ class nodeClass {
?.type("flow")
?.variant("predicted")
?.position("atequipment")
?.getCurrentValue('m3/h') || 0;
?.getCurrentValue(mg?.unitPolicy?.output?.flow || 'm3/h') || 0;
const totalPower = mg.measurements
?.type("power")
?.variant("predicted")
?.position("atEquipment")
?.getCurrentValue() || 0;
?.getCurrentValue(mg?.unitPolicy?.output?.power || 'kW') || 0;
// Calculate total capacity based on available machines with safety checks
const availableMachines = Object.values(mg.machines || {}).filter((machine) => {
// Safety check: ensure machine and machine.state exist
if (!machine || !machine.state || typeof machine.state.getCurrentState !== 'function') {
console.warn(`Machine missing or invalid:`, machine?.config?.general?.id || 'unknown');
mg.logger?.warn(`Machine missing or invalid: ${machine?.config?.general?.id || 'unknown'}`);
return false;
}
@@ -197,64 +204,62 @@ class nodeClass {
async (msg, send, done) => {
const mg = this.source;
const RED = this.RED;
try {
switch (msg.topic) {
case "registerChild":
//console.log(`Registering child in mgc: ${msg.payload}`);
case "registerChild": {
const childId = msg.payload;
const childObj = RED.nodes.getNode(childId);
// Debug: Check what we're getting
//console.log(`Child object:`, childObj ? 'found' : 'NOT FOUND');
//console.log(`Child source:`, childObj?.source ? 'exists' : 'MISSING');
if (childObj?.source) {
//console.log(`Child source type:`, childObj.source.constructor.name);
//console.log(`Child has state:`, !!childObj.source.state);
if (!childObj || !childObj.source) {
mg.logger.warn(`registerChild skipped: missing child/source for id=${childId}`);
break;
}
mg.childRegistrationUtils.registerChild(
childObj.source,
msg.positionVsParent
);
mg.logger.debug(`Registering child: ${childId}, found: ${!!childObj}, source: ${!!childObj?.source}`);
// Debug: Check machines after registration
//console.log(`Total machines after registration:`, Object.keys(mg.machines || {}).length);
mg.childRegistrationUtils.registerChild(childObj.source, msg.positionVsParent);
mg.logger.debug(`Total machines after registration: ${Object.keys(mg.machines || {}).length}`);
break;
}
case "setMode":
case "setMode": {
const mode = msg.payload;
mg.setMode(mode);
break;
case "setScaling":
const scaling = msg.payload;
mg.setScaling(scaling);
break;
case "Qd":
const Qd = parseFloat(msg.payload);
const sourceQd = "parent";
if (isNaN(Qd)) {
return mg.logger.error(`Invalid demand value: ${Qd}`);
}
case "setScaling": {
const scaling = msg.payload;
mg.setScaling(scaling);
break;
}
case "Qd": {
const Qd = parseFloat(msg.payload);
const sourceQd = "parent";
if (isNaN(Qd)) {
mg.logger.error(`Invalid demand value: ${msg.payload}`);
break;
}
try {
await mg.handleInput(sourceQd, Qd);
msg.topic = mg.config.general.name;
msg.payload = "done";
send(msg);
} catch (e) {
console.log(e);
} catch (error) {
mg.logger.error(`Failed to process Qd: ${error.message}`);
}
break;
}
default:
// Handle unknown topics if needed
mg.logger.warn(`Unknown topic: ${msg.topic}`);
break;
}
done();
} catch (error) {
mg.logger.error(`Input handler failure: ${error.message}`);
}
if (typeof done === 'function') done();
}
);
}
@@ -266,7 +271,7 @@ class nodeClass {
this.node.on("close", (done) => {
clearInterval(this._tickInterval);
clearInterval(this._statusInterval);
done();
if (typeof done === 'function') done();
});
}
}

349
src/specificClass.js
View File

@@ -1,7 +1,25 @@
//load local dependencies
const EventEmitter = require("events");
const {logger,configUtils,configManager, MeasurementContainer, interpolation , childRegistrationUtils} = require('generalFunctions');
const {logger,configUtils,configManager, MeasurementContainer, interpolation , childRegistrationUtils, convert, POSITIONS} = require('generalFunctions');
const CANONICAL_UNITS = Object.freeze({
pressure: 'Pa',
flow: 'm3/s',
power: 'W',
temperature: 'K',
});
const DEFAULT_IO_UNITS = Object.freeze({
pressure: 'mbar',
flow: 'm3/h',
power: 'kW',
temperature: 'C',
});
/**
* Machine group controller domain model.
* Aggregates multiple rotating machines and coordinates group-level optimization/control.
*/
class MachineGroup {
constructor(machineGroupConfig = {}) {
@@ -10,6 +28,12 @@ class MachineGroup {
this.defaultConfig = this.configManager.getConfig('machineGroupControl'); // Load default config for rotating machine ( use software type name ? )
this.configUtils = new configUtils(this.defaultConfig);// this will handle the config endpoints so we can load them dynamically
this.config = this.configUtils.initConfig(machineGroupConfig); // verify and set the config for the machine group
this.unitPolicy = this._buildUnitPolicy(this.config);
this.config = this.configUtils.updateConfig(this.config, {
general: {
unit: this.unitPolicy.output.flow,
}
});
// Init after config is set
this.logger = new logger(this.config.general.logging.enabled,this.config.general.logging.logLevel, this.config.general.name);
@@ -19,11 +43,22 @@ class MachineGroup {
autoConvert: true,
windowSize: 50,
defaultUnits: {
pressure: 'mbar',
flow: 'l/s',
power: 'kW',
temperature: 'C'
}
pressure: this.unitPolicy.output.pressure,
flow: this.unitPolicy.output.flow,
power: this.unitPolicy.output.power,
temperature: this.unitPolicy.output.temperature
},
preferredUnits: {
pressure: this.unitPolicy.output.pressure,
flow: this.unitPolicy.output.flow,
power: this.unitPolicy.output.power,
temperature: this.unitPolicy.output.temperature
},
canonicalUnits: this.unitPolicy.canonical,
storeCanonical: true,
strictUnitValidation: true,
throwOnInvalidUnit: true,
requireUnitForTypes: ['pressure', 'flow', 'power', 'temperature']
});
this.interpolation = new interpolation();
@@ -50,7 +85,8 @@ class MachineGroup {
registerChild(child,softwareType) {
this.logger.debug('Setting up childs specific for this class');
const position = child.config.general.positionVsParent;
// Prefer functionality-scoped position metadata; keep general fallback for legacy nodes.
const position = child.config?.functionality?.positionVsParent || child.config?.general?.positionVsParent;
if(softwareType == "machine"){
// Check if the machine is already registered
@@ -87,7 +123,7 @@ class MachineGroup {
Object.values(this.machines).forEach(machine => {
const totals = { flow: { min: Infinity, max: 0 }, power: { min: Infinity, max: 0 } };
//fetch min flow ever seen over all machines
Object.entries(machine.predictFlow.inputCurve).forEach(([pressure, xyCurve], index) => {
Object.entries(machine.predictFlow.inputCurve).forEach(([pressure, xyCurve], _index) => {
const minFlow = Math.min(...xyCurve.y);
const maxFlow = Math.max(...xyCurve.y);
@@ -160,8 +196,8 @@ class MachineGroup {
const minPower = machine.predictPower.currentFxyYMin;
const maxPower = machine.predictPower.currentFxyYMax;
const actFlow = machine.measurements.type("flow").variant("predicted").position("atequipment").getCurrentValue();
const actPower = machine.measurements.type("power").variant("predicted").position("atequipment").getCurrentValue();
const actFlow = this._readChildMeasurement(machine, "flow", "predicted", POSITIONS.DOWNSTREAM, this.unitPolicy.canonical.flow) || 0;
const actPower = this._readChildMeasurement(machine, "power", "predicted", POSITIONS.AT_EQUIPMENT, this.unitPolicy.canonical.power) || 0;
this.logger.debug(`Machine ${machine.config.general.id} - Min Flow: ${minFlow}, Max Flow: ${maxFlow}, Min Power: ${minPower}, Max Power: ${maxPower}, NCog: ${machine.NCog}`);
@@ -210,16 +246,16 @@ class MachineGroup {
}
handlePressureChange() {
this.logger.info("---------------------->>>>>>>>>>>>>>>>>>>>>>>>>>>Pressure change detected.");
this.logger.debug("Pressure change detected.");
// Recalculate totals
const { flow, power } = this.calcDynamicTotals();
this.logger.debug(`Dynamic Totals after pressure change - Flow: Min ${flow.min}, Max ${flow.max}, Act ${flow.act} | Power: Min ${power.min}, Max ${power.max}, Act ${power.act}`);
this.measurements.type("flow").variant("predicted").position("atequipment").value(flow.act);
this.measurements.type("power").variant("predicted").position("atequipment").value(power.act);
this._writeMeasurement("flow", "predicted", POSITIONS.AT_EQUIPMENT, flow.act, this.unitPolicy.canonical.flow);
this._writeMeasurement("power", "predicted", POSITIONS.AT_EQUIPMENT, power.act, this.unitPolicy.canonical.power);
const { maxEfficiency, lowestEfficiency } = this.calcGroupEfficiency(this.machines);
const efficiency = this.measurements.type("efficiency").variant("predicted").position("atequipment").getCurrentValue();
const efficiency = this.measurements.type("efficiency").variant("predicted").position(POSITIONS.AT_EQUIPMENT).getCurrentValue();
this.calcDistanceBEP(efficiency,maxEfficiency,lowestEfficiency);
}
@@ -229,7 +265,7 @@ class MachineGroup {
calcRelativeDistanceFromPeak(currentEfficiency,maxEfficiency,minEfficiency){
let distance = 1;
if(currentEfficiency != null){
if(currentEfficiency != null && maxEfficiency !== minEfficiency){
distance = this.interpolation.interpolate_lin_single_point(currentEfficiency,maxEfficiency, minEfficiency, 0, 1);
}
return distance;
@@ -255,11 +291,13 @@ class MachineGroup {
//add special cases
if( state === "operational" && ( mode == "virtualControl" || mode === "fysicalControl") ){
let flow = 0;
if(machine.measurements.type("flow").variant("measured").position("downstream").getCurrentValue()){
flow = machine.measurements.type("flow").variant("measured").position("downstream").getCurrentValue();
const measuredFlow = this._readChildMeasurement(machine, "flow", "measured", POSITIONS.DOWNSTREAM, this.unitPolicy.canonical.flow);
const predictedFlow = this._readChildMeasurement(machine, "flow", "predicted", POSITIONS.DOWNSTREAM, this.unitPolicy.canonical.flow);
if (Number.isFinite(measuredFlow) && measuredFlow !== 0) {
flow = measuredFlow;
}
else if(machine.measurements.type("flow").variant("predicted").position("atequipment").getCurrentValue()){
flow = machine.measurements.type("flow").variant("predicted").position("atequipment").getCurrentValue();
else if (Number.isFinite(predictedFlow) && predictedFlow !== 0) {
flow = predictedFlow;
}
else{
this.logger.error("Dont perform calculation at all seeing that there is a machine working but we dont know the flow its producing");
@@ -542,14 +580,40 @@ class MachineGroup {
this.redistributeFlowBySlope(pumpInfos, flowDistribution, delta, directional);
}
// Clamp and compute initial power
flowDistribution.forEach(entry => {
const info = pumpInfos.find(info => info.id === entry.machineId);
entry.flow = Math.min(info.maxFlow, Math.max(info.minFlow, entry.flow));
});
// Marginal-cost refinement: shift flow from most expensive to cheapest
// pump using actual power evaluations. Converges regardless of curve convexity.
const mcDelta = Math.max(1e-6, (Qd / pumpInfos.length) * 0.005);
for (let refineIter = 0; refineIter < 50; refineIter++) {
const mcEntries = flowDistribution.map(entry => {
const info = pumpInfos.find(i => i.id === entry.machineId);
const pNow = info.machine.inputFlowCalcPower(entry.flow);
const pUp = info.machine.inputFlowCalcPower(Math.min(info.maxFlow, entry.flow + mcDelta));
return { entry, info, mc: (pUp - pNow) / mcDelta };
});
let expensive = null, cheap = null;
for (const e of mcEntries) {
if (e.entry.flow > e.info.minFlow + mcDelta) { if (!expensive || e.mc > expensive.mc) expensive = e; }
if (e.entry.flow < e.info.maxFlow - mcDelta) { if (!cheap || e.mc < cheap.mc) cheap = e; }
}
if (!expensive || !cheap || expensive === cheap) break;
if (expensive.mc - cheap.mc < expensive.mc * 0.001) break;
const before = expensive.info.machine.inputFlowCalcPower(expensive.entry.flow) + cheap.info.machine.inputFlowCalcPower(cheap.entry.flow);
const after = expensive.info.machine.inputFlowCalcPower(expensive.entry.flow - mcDelta) + cheap.info.machine.inputFlowCalcPower(cheap.entry.flow + mcDelta);
if (after < before) { expensive.entry.flow -= mcDelta; cheap.entry.flow += mcDelta; } else { break; }
}
let totalPower = 0;
totalFlow = 0;
flowDistribution.forEach(entry => {
const info = pumpInfos.find(info => info.id === entry.machineId);
const flow = Math.min(info.maxFlow, Math.max(info.minFlow, entry.flow));
entry.flow = flow;
totalFlow += flow;
totalPower += info.machine.inputFlowCalcPower(flow);
totalFlow += entry.flow;
const info = pumpInfos.find(i => i.id === entry.machineId);
totalPower += info.machine.inputFlowCalcPower(entry.flow);
});
const totalCog = pumpInfos.reduce((sum, info) => sum + info.NCog, 0);
@@ -607,12 +671,17 @@ class MachineGroup {
async optimalControl(Qd, powerCap = Infinity) {
try{
if (Object.keys(this.machines).length === 0) {
this.logger.warn("No machines registered. Cannot execute optimal control.");
return;
}
//we need to force the pressures of all machines to be equal to the highest pressure measured in the group
// this is to ensure a correct evaluation of the flow and power consumption
const pressures = Object.entries(this.machines).map(([machineId, machine]) => {
const pressures = Object.entries(this.machines).map(([_machineId, machine]) => {
return {
downstream: machine.measurements.type("pressure").variant("measured").position("downstream").getCurrentValue(),
upstream: machine.measurements.type("pressure").variant("measured").position("upstream").getCurrentValue()
downstream: this._readChildMeasurement(machine, "pressure", "measured", POSITIONS.DOWNSTREAM, this.unitPolicy.canonical.pressure) || 0,
upstream: this._readChildMeasurement(machine, "pressure", "measured", POSITIONS.UPSTREAM, this.unitPolicy.canonical.pressure) || 0
};
});
@@ -622,12 +691,12 @@ class MachineGroup {
this.logger.debug(`Max downstream pressure: ${maxDownstream}, Min upstream pressure: ${minUpstream}`);
//set the pressures
Object.entries(this.machines).forEach(([machineId, machine]) => {
Object.entries(this.machines).forEach(([_machineId, machine]) => {
if(machine.state.getCurrentState() !== "operational" && machine.state.getCurrentState() !== "accelerating" && machine.state.getCurrentState() !== "decelerating"){
//Equilize pressures over all machines so we can make a proper calculation
machine.measurements.type("pressure").variant("measured").position("downstream").value(maxDownstream);
machine.measurements.type("pressure").variant("measured").position("upstream").value(minUpstream);
this._writeChildMeasurement(machine, "pressure", "measured", POSITIONS.DOWNSTREAM, maxDownstream, this.unitPolicy.canonical.pressure);
this._writeChildMeasurement(machine, "pressure", "measured", POSITIONS.UPSTREAM, minUpstream, this.unitPolicy.canonical.pressure);
// after updating the measurement directly we need to force the update of the value OLIFANT this is not so clear now in the code
// we need to find a better way to do this but for now it works
@@ -644,7 +713,9 @@ class MachineGroup {
}, {});
if( Qd <= 0 ) {
//if Qd is 0 turn all machines off and exit early
this.logger.debug("Flow demand <= 0, turning all machines off.");
await this.turnOffAllMachines();
return;
}
if( Qd < dynamicTotals.flow.min && Qd > 0 ){
@@ -690,10 +761,10 @@ class MachineGroup {
this.logger.debug(`Moving to demand: ${Qd.toFixed(2)} -> Pumps: [${debugInfo}] => Total Power: ${bestResult.bestPower.toFixed(2)}`);
//store the total delivered power
this.measurements.type("power").variant("predicted").position("atequipment").value(bestResult.bestPower);
this.measurements.type("flow").variant("predicted").position("atequipment").value(bestResult.bestFlow);
this.measurements.type("efficiency").variant("predicted").position("atequipment").value(bestResult.bestFlow / bestResult.bestPower);
this.measurements.type("Ncog").variant("predicted").position("atequipment").value(bestResult.bestCog);
this._writeMeasurement("power", "predicted", POSITIONS.AT_EQUIPMENT, bestResult.bestPower, this.unitPolicy.canonical.power);
this._writeMeasurement("flow", "predicted", POSITIONS.DOWNSTREAM, bestResult.bestFlow, this.unitPolicy.canonical.flow);
this.measurements.type("efficiency").variant("predicted").position(POSITIONS.AT_EQUIPMENT).value(bestResult.bestFlow / bestResult.bestPower);
this.measurements.type("Ncog").variant("predicted").position(POSITIONS.AT_EQUIPMENT).value(bestResult.bestCog);
await Promise.all(Object.entries(this.machines).map(async ([machineId, machine]) => {
// Find the flow for this machine in the best combination
@@ -713,11 +784,11 @@ class MachineGroup {
if(machineStates[machineId] === "idle" && flow > 0){
await machine.handleInput("parent", "execsequence", "startup");
await machine.handleInput("parent", "flowmovement", flow);
await machine.handleInput("parent", "flowmovement", this._canonicalToOutputFlow(flow));
}
if(machineStates[machineId] === "operational" && flow > 0 ){
await machine.handleInput("parent", "flowmovement", flow);
await machine.handleInput("parent", "flowmovement", this._canonicalToOutputFlow(flow));
}
}));
}
@@ -728,11 +799,13 @@ class MachineGroup {
// Equalize pressure across all machines for machines that are not running. This is needed to ensure accurate flow and power predictions.
equalizePressure(){
if (Object.keys(this.machines).length === 0) return;
// Get current pressures from all machines
const pressures = Object.entries(this.machines).map(([machineId, machine]) => {
const pressures = Object.entries(this.machines).map(([_machineId, machine]) => {
return {
downstream: machine.measurements.type("pressure").variant("measured").position("downstream").getCurrentValue(),
upstream: machine.measurements.type("pressure").variant("measured").position("upstream").getCurrentValue()
downstream: this._readChildMeasurement(machine, "pressure", "measured", POSITIONS.DOWNSTREAM, this.unitPolicy.canonical.pressure) || 0,
upstream: this._readChildMeasurement(machine, "pressure", "measured", POSITIONS.UPSTREAM, this.unitPolicy.canonical.pressure) || 0
};
});
@@ -743,8 +816,8 @@ class MachineGroup {
// Set consistent pressures across machines
Object.entries(this.machines).forEach(([machineId, machine]) => {
if(!this.isMachineActive(machineId)){
machine.measurements.type("pressure").variant("measured").position("downstream").value(maxDownstream);
machine.measurements.type("pressure").variant("measured").position("upstream").value(minUpstream);
this._writeChildMeasurement(machine, "pressure", "measured", POSITIONS.DOWNSTREAM, maxDownstream, this.unitPolicy.canonical.pressure);
this._writeChildMeasurement(machine, "pressure", "measured", POSITIONS.UPSTREAM, minUpstream, this.unitPolicy.canonical.pressure);
// Update the measured pressure value
const pressure = machine.getMeasuredPressure();
this.logger.debug(`Setting pressure for machine ${machineId} to ${pressure}`);
@@ -788,7 +861,7 @@ class MachineGroup {
}
filterOutUnavailableMachines(list) {
const newList = list.filter(({ id, machine }) => {
const newList = list.filter(({ machine }) => {
const state = machine.state.getCurrentState();
const validActionForMode = machine.isValidActionForMode("execsequence", "auto");
@@ -803,7 +876,7 @@ class MachineGroup {
let lowestEfficiency = Infinity;
// Calculate the average efficiency of all machines -> peak is the average of them all
Object.entries(machines).forEach(([machineId, machine]) => {
Object.entries(machines).forEach(([_machineId, machine]) => {
cumEfficiency += machine.cog;
if(machine.cog < lowestEfficiency){
lowestEfficiency = machine.cog;
@@ -818,7 +891,7 @@ class MachineGroup {
}
//move machines assuming equal control in flow and a priority list
async equalFlowControl(Qd, powerCap = Infinity, priorityList = null) {
async equalFlowControl(Qd, _powerCap = Infinity, priorityList = null) {
try {
// equalize pressure across all machines
@@ -873,7 +946,7 @@ class MachineGroup {
break;
}
case (Qd > activeTotals.flow.max):
case (Qd > activeTotals.flow.max): {
// Case 2: Demand is above the maximum available flow.
// Start the non-active machine with the highest priority and distribute Qd over all available machines.
let i = 1;
@@ -893,9 +966,10 @@ class MachineGroup {
}
break;
}
default:
default: {
// Default case: Demand is within the active range.
const countActiveMachines = machinesInPriorityOrder.filter(({ id }) => this.isMachineActive(id)).length;
@@ -910,6 +984,7 @@ class MachineGroup {
}
break;
}
}
// Log information about flow distribution
const debugInfo = flowDistribution
@@ -920,10 +995,10 @@ class MachineGroup {
this.logger.debug(`Priority control for demand: ${totalFlow.toFixed(2)} -> Active pumps: [${debugInfo}] => Total Power: ${totalPower.toFixed(2)}`);
// Store measurements
this.measurements.type("power").variant("predicted").position("atequipment").value(totalPower);
this.measurements.type("flow").variant("predicted").position("atequipment").value(totalFlow);
this.measurements.type("efficiency").variant("predicted").position("atequipment").value(totalFlow / totalPower);
this.measurements.type("Ncog").variant("predicted").position("atequipment").value(totalCog);
this._writeMeasurement("power", "predicted", POSITIONS.AT_EQUIPMENT, totalPower, this.unitPolicy.canonical.power);
this._writeMeasurement("flow", "predicted", POSITIONS.DOWNSTREAM, totalFlow, this.unitPolicy.canonical.flow);
this.measurements.type("efficiency").variant("predicted").position(POSITIONS.AT_EQUIPMENT).value(totalFlow / totalPower);
this.measurements.type("Ncog").variant("predicted").position(POSITIONS.AT_EQUIPMENT).value(totalCog);
this.logger.debug(`Flow distribution: ${JSON.stringify(flowDistribution)}`);
// Apply the flow distribution to machines
@@ -937,9 +1012,10 @@ class MachineGroup {
}
else if (currentState === "idle" && flow > 0) {
await machine.handleInput("parent", "execsequence", "startup");
await machine.handleInput("parent", "flowmovement", this._canonicalToOutputFlow(flow));
}
else if (currentState === "operational" && flow > 0) {
await machine.handleInput("parent", "flowmovement", flow);
await machine.handleInput("parent", "flowmovement", this._canonicalToOutputFlow(flow));
}
}));
}
@@ -961,7 +1037,7 @@ class MachineGroup {
}
//capp input to 100
input > 100 ? input = 100 : input = input;
if (input > 100) { input = 100; }
const numOfMachines = Object.keys(this.machines).length;
const procentTotal = numOfMachines * input;
@@ -975,7 +1051,7 @@ class MachineGroup {
if(machinesNeeded > machinesActive){
//start extra machine and put all active machines at min control
machinesInPriorityOrder.forEach(({ id, machine }, index) => {
machinesInPriorityOrder.forEach(({ id }, index) => {
if(index < machinesNeeded){
ctrlDistribution.push({machineId : id, ctrl : 0});
}
@@ -984,7 +1060,7 @@ class MachineGroup {
if(machinesNeeded < machinesActive){
machinesInPriorityOrder.forEach(({ id, machine }, index) => {
machinesInPriorityOrder.forEach(({ id }, index) => {
if(this.isMachineActive(id)){
if(index < machinesNeeded){
ctrlDistribution.push({machineId : id, ctrl : 100});
@@ -1001,7 +1077,7 @@ class MachineGroup {
// distribute input equally among active machines (0 - 100%)
const ctrlPerMachine = procentTotal / machinesActive;
machinesInPriorityOrder.forEach(({ id, machine }) => {
machinesInPriorityOrder.forEach(({ id }) => {
if (this.isMachineActive(id)) {
// ensure ctrl is capped between 0 and 100%
const ctrlValue = Math.max(0, Math.min(ctrlPerMachine, 100));
@@ -1033,10 +1109,10 @@ class MachineGroup {
const totalFlow = [];
// fetch and store measurements
Object.entries(this.machines).forEach(([machineId, machine]) => {
Object.entries(this.machines).forEach(([_machineId, machine]) => {
const powerValue = machine.measurements.type("power").variant("predicted").position("atequipment").getCurrentValue();
const flowValue = machine.measurements.type("flow").variant("predicted").position("atequipment").getCurrentValue();
const powerValue = this._readChildMeasurement(machine, "power", "predicted", POSITIONS.AT_EQUIPMENT, this.unitPolicy.canonical.power);
const flowValue = this._readChildMeasurement(machine, "flow", "predicted", POSITIONS.DOWNSTREAM, this.unitPolicy.canonical.flow);
if (powerValue !== null) {
totalPower.push(powerValue);
@@ -1046,11 +1122,11 @@ class MachineGroup {
}
});
this.measurements.type("power").variant("predicted").position("atequipment").value(totalPower.reduce((a, b) => a + b, 0));
this.measurements.type("flow").variant("predicted").position("atequipment").value(totalFlow.reduce((a, b) => a + b, 0));
this._writeMeasurement("power", "predicted", POSITIONS.AT_EQUIPMENT, totalPower.reduce((a, b) => a + b, 0), this.unitPolicy.canonical.power);
this._writeMeasurement("flow", "predicted", POSITIONS.DOWNSTREAM, totalFlow.reduce((a, b) => a + b, 0), this.unitPolicy.canonical.flow);
if(totalPower.reduce((a, b) => a + b, 0) > 0){
this.measurements.type("efficiency").variant("predicted").position("atequipment").value(totalFlow.reduce((a, b) => a + b, 0) / totalPower.reduce((a, b) => a + b, 0));
this.measurements.type("efficiency").variant("predicted").position(POSITIONS.AT_EQUIPMENT).value(totalFlow.reduce((a, b) => a + b, 0) / totalPower.reduce((a, b) => a + b, 0));
}
}
@@ -1086,18 +1162,19 @@ class MachineGroup {
return;
}
if (demandQ < absoluteTotals.flow.min) {
this.logger.warn(`Flow demand ${demandQ} is below minimum possible flow ${absoluteTotals.flow.min}. Capping to minimum flow.`);
demandQout = this.absoluteTotals.flow.min;
} else if (demandQout > absoluteTotals.flow.max) {
this.logger.warn(`Flow demand ${demandQ} is above maximum possible flow ${absoluteTotals.flow.max}. Capping to maximum flow.`);
demandQout = absoluteTotals.flow.max;
}else if(demandQout <= 0){
if (demandQ <= 0) {
this.logger.debug(`Turning machines off`);
demandQout = 0;
//return early and turn all machines off
this.turnOffAllMachines();
return;
} else if (demandQ < this.absoluteTotals.flow.min) {
this.logger.warn(`Flow demand ${demandQ} is below minimum possible flow ${this.absoluteTotals.flow.min}. Capping to minimum flow.`);
demandQout = this.absoluteTotals.flow.min;
} else if (demandQ > this.absoluteTotals.flow.max) {
this.logger.warn(`Flow demand ${demandQ} is above maximum possible flow ${this.absoluteTotals.flow.max}. Capping to maximum flow.`);
demandQout = this.absoluteTotals.flow.max;
} else {
demandQout = demandQ;
}
break;
@@ -1147,7 +1224,7 @@ class MachineGroup {
//recalc distance from BEP
const { maxEfficiency, lowestEfficiency } = this.calcGroupEfficiency(this.machines);
const efficiency = this.measurements.type("efficiency").variant("predicted").position("downstream").getCurrentValue();
const efficiency = this.measurements.type("efficiency").variant("predicted").position(POSITIONS.AT_EQUIPMENT).getCurrentValue();
this.calcDistanceBEP(efficiency,maxEfficiency,lowestEfficiency);
}
@@ -1158,6 +1235,113 @@ class MachineGroup {
}));
}
_buildUnitPolicy(config = {}) {
const flowUnit = this._resolveUnitOrFallback(
config?.general?.unit,
'volumeFlowRate',
DEFAULT_IO_UNITS.flow
);
const pressureUnit = this._resolveUnitOrFallback(
config?.general?.pressureUnit,
'pressure',
DEFAULT_IO_UNITS.pressure
);
const powerUnit = this._resolveUnitOrFallback(
config?.general?.powerUnit,
'power',
DEFAULT_IO_UNITS.power
);
return {
canonical: { ...CANONICAL_UNITS },
output: {
flow: flowUnit,
pressure: pressureUnit,
power: powerUnit,
temperature: DEFAULT_IO_UNITS.temperature,
},
};
}
_resolveUnitOrFallback(candidate, expectedMeasure, fallbackUnit) {
const fallback = String(fallbackUnit || '').trim();
const raw = typeof candidate === 'string' ? candidate.trim() : '';
if (!raw) {
return fallback;
}
try {
const desc = convert().describe(raw);
if (expectedMeasure && desc.measure !== expectedMeasure) {
throw new Error(`expected '${expectedMeasure}', got '${desc.measure}'`);
}
return raw;
} catch (error) {
this.logger?.warn?.(`Invalid unit '${raw}' (${error.message}); falling back to '${fallback}'.`);
return fallback;
}
}
_canonicalToOutputFlow(value) {
const from = this.unitPolicy.canonical.flow;
const to = this.unitPolicy.output.flow;
if (!from || !to || from === to) return value;
return convert(value).from(from).to(to);
}
_outputUnitForType(type) {
switch (String(type || '').toLowerCase()) {
case 'flow':
return this.unitPolicy.output.flow;
case 'power':
return this.unitPolicy.output.power;
case 'pressure':
return this.unitPolicy.output.pressure;
case 'temperature':
return this.unitPolicy.output.temperature;
default:
return null;
}
}
_readMeasurement(type, variant, position, unit = null) {
const requestedUnit = unit || this._outputUnitForType(type);
return this.measurements
.type(type)
.variant(variant)
.position(position)
.getCurrentValue(requestedUnit || undefined);
}
_writeMeasurement(type, variant, position, value, unit = null, timestamp = Date.now()) {
if (!Number.isFinite(value)) {
return;
}
this.measurements
.type(type)
.variant(variant)
.position(position)
.value(value, timestamp, unit || undefined);
}
_readChildMeasurement(machine, type, variant, position, unit = null) {
return machine?.measurements
?.type(type)
?.variant(variant)
?.position(position)
?.getCurrentValue(unit || undefined);
}
_writeChildMeasurement(machine, type, variant, position, value, unit = null, timestamp = Date.now()) {
if (!machine?.measurements || !Number.isFinite(value)) {
return;
}
machine.measurements
.type(type)
.variant(variant)
.position(position)
.value(value, timestamp, unit || undefined);
}
setMode(mode) {
this.mode = mode;
}
@@ -1170,10 +1354,10 @@ class MachineGroup {
//build the output object
this.measurements.getTypes().forEach(type => {
this.measurements.getVariants(type).forEach(variant => {
const downstreamVal = this.measurements.type(type).variant(variant).position("downstream").getCurrentValue();
const atEquipmentVal = this.measurements.type(type).variant(variant).position("atequipment").getCurrentValue();
const upstreamVal = this.measurements.type(type).variant(variant).position("upstream").getCurrentValue();
const unit = this._outputUnitForType(type);
const downstreamVal = this._readMeasurement(type, variant, POSITIONS.DOWNSTREAM, unit);
const atEquipmentVal = this._readMeasurement(type, variant, POSITIONS.AT_EQUIPMENT, unit);
const upstreamVal = this._readMeasurement(type, variant, POSITIONS.UPSTREAM, unit);
if (downstreamVal != null) {
output[`downstream_${variant}_${type}`] = downstreamVal;
@@ -1182,11 +1366,16 @@ class MachineGroup {
output[`upstream_${variant}_${type}`] = upstreamVal;
}
if (atEquipmentVal != null) {
output[`atequipment${variant}_${type}`] = atEquipmentVal;
output[`atEquipment_${variant}_${type}`] = atEquipmentVal;
}
if (downstreamVal != null && upstreamVal != null) {
const diffVal = this.measurements.type(type).variant(variant).difference().value;
output[`differential_${variant}_${type}`] = diffVal;
const diff = this.measurements
.type(type)
.variant(variant)
.difference({ from: POSITIONS.DOWNSTREAM, to: POSITIONS.UPSTREAM, unit });
if (diff?.value != null) {
output[`differential_${variant}_${type}`] = diff.value;
}
}
});
});
@@ -1396,6 +1585,8 @@ async function makeMachines(){
}
makeMachines();
if (require.main === module) {
makeMachines();
}
//*/

12
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@@ -0,0 +1,12 @@
# machineGroupControl Test Suite Layout
Required EVOLV layout:
- basic/
- integration/
- edge/
- helpers/
Baseline structure tests:
- basic/structure-module-load.basic.test.js
- integration/structure-examples.integration.test.js
- edge/structure-examples-node-type.edge.test.js

0
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8
test/basic/structure-module-load.basic.test.js Normal file
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@@ -0,0 +1,8 @@
const test = require('node:test');
const assert = require('node:assert/strict');
test('machineGroupControl module load smoke', () => {
assert.doesNotThrow(() => {
require('../../mgc.js');
});
});

0
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11
test/edge/structure-examples-node-type.edge.test.js Normal file
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@@ -0,0 +1,11 @@
const test = require('node:test');
const assert = require('node:assert/strict');
const fs = require('node:fs');
const path = require('node:path');
const flow = JSON.parse(fs.readFileSync(path.resolve(__dirname, '../../examples/basic.flow.json'), 'utf8'));
test('basic example includes node type machineGroupControl', () => {
const count = flow.filter((n) => n && n.type === 'machineGroupControl').length;
assert.equal(count >= 1, true);
});

0
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0
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227
test/integration/distribution-power-table.integration.test.js Normal file
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@@ -0,0 +1,227 @@
/**
* machineGroupControl vs naive strategies — real pump curves
*
* Station: 2× hidrostal H05K-S03R + 1× hidrostal C5-D03R-SHN1
* ΔP = 2000 mbar
*
* Compares the ACTUAL machineGroupControl optimalControl algorithm against
* naive baselines. All strategies must deliver exactly Qd.
*/
const test = require('node:test');
const assert = require('node:assert/strict');
const MachineGroup = require('../../src/specificClass');
const Machine = require('../../../rotatingMachine/src/specificClass');
const DIFF_MBAR = 2000;
const UP_MBAR = 500;
const DOWN_MBAR = UP_MBAR + DIFF_MBAR;
const stateConfig = {
time: { starting: 0, warmingup: 0, stopping: 0, coolingdown: 0 },
movement: { speed: 1200, mode: 'staticspeed', maxSpeed: 1800 }
};
function machineConfig(id, model) {
return {
general: { logging: { enabled: false, logLevel: 'error' }, name: id, id, unit: 'm3/h' },
functionality: { softwareType: 'machine', role: 'rotationaldevicecontroller' },
asset: { category: 'pump', type: 'centrifugal', model, supplier: 'hidrostal' },
mode: {
current: 'auto',
allowedActions: { auto: ['execsequence', 'execmovement', 'flowmovement', 'statuscheck'] },
allowedSources: { auto: ['parent', 'GUI'] }
},
sequences: {
startup: ['starting', 'warmingup', 'operational'],
shutdown: ['stopping', 'coolingdown', 'idle'],
emergencystop: ['emergencystop', 'off'],
}
};
}
function groupConfig() {
return {
general: { logging: { enabled: false, logLevel: 'error' }, name: 'station' },
functionality: { softwareType: 'machinegroup', role: 'groupcontroller' },
scaling: { current: 'absolute' },
mode: { current: 'optimalcontrol' }
};
}
function injectPressure(m) {
m.updateMeasuredPressure(UP_MBAR, 'upstream', { timestamp: Date.now(), unit: 'mbar', childName: 'up', childId: `up-${m.config.general.id}` });
m.updateMeasuredPressure(DOWN_MBAR, 'downstream', { timestamp: Date.now(), unit: 'mbar', childName: 'dn', childId: `dn-${m.config.general.id}` });
}
/* ---- naive baselines (pumps OFF = 0 flow, 0 power) ---- */
function distribute(machines, running, rawDist, Qd) {
const dist = {};
for (const id of Object.keys(machines)) dist[id] = 0;
for (const id of running) {
const m = machines[id];
dist[id] = Math.min(m.predictFlow.currentFxyYMax, Math.max(m.predictFlow.currentFxyYMin, rawDist[id] || 0));
}
for (let pass = 0; pass < 20; pass++) {
let rem = Qd - running.reduce((s, id) => s + dist[id], 0);
if (Math.abs(rem) < 1e-9) break;
for (const id of running) {
if (Math.abs(rem) < 1e-9) break;
const m = machines[id];
const cap = rem > 0 ? m.predictFlow.currentFxyYMax - dist[id] : dist[id] - m.predictFlow.currentFxyYMin;
if (cap > 1e-9) { const t = Math.min(Math.abs(rem), cap); dist[id] += rem > 0 ? t : -t; rem += rem > 0 ? -t : t; }
}
}
return dist;
}
function spillover(machines, Qd) {
const sorted = Object.keys(machines).sort((a, b) => machines[a].predictFlow.currentFxyYMax - machines[b].predictFlow.currentFxyYMax);
let running = [], maxCap = 0;
for (const id of sorted) { running.push(id); maxCap += machines[id].predictFlow.currentFxyYMax; if (maxCap >= Qd) break; }
const raw = {}; let rem = Qd;
for (const id of running) { raw[id] = rem; rem = Math.max(0, rem - machines[id].predictFlow.currentFxyYMax); }
const dist = distribute(machines, running, raw, Qd);
let p = 0, f = 0;
for (const id of running) { p += machines[id].inputFlowCalcPower(dist[id]); f += dist[id]; }
return { dist, power: p, flow: f, combo: running };
}
function equalAllOn(machines, Qd) {
const ids = Object.keys(machines);
const raw = {}; for (const id of ids) raw[id] = Qd / ids.length;
const dist = distribute(machines, ids, raw, Qd);
let p = 0, f = 0;
for (const id of ids) { p += machines[id].inputFlowCalcPower(dist[id]); f += dist[id]; }
return { dist, power: p, flow: f, combo: ids };
}
/* ---- test ---- */
test('machineGroupControl vs naive baselines — real curves, verified flow', async () => {
const mg = new MachineGroup(groupConfig());
const machines = {};
for (const [id, model] of [['H05K-1','hidrostal-H05K-S03R'],['H05K-2','hidrostal-H05K-S03R'],['C5','hidrostal-C5-D03R-SHN1']]) {
const m = new Machine(machineConfig(id, model), stateConfig);
injectPressure(m);
mg.childRegistrationUtils.registerChild(m, 'downstream');
machines[id] = m;
}
const toH = (v) => +(v * 3600).toFixed(1);
const CANON_FLOW = 'm3/s';
const CANON_POWER = 'W';
console.log(`\n=== STATION: 2×H05K + 1×C5 @ ΔP=${DIFF_MBAR} mbar ===`);
console.table(Object.entries(machines).map(([id, m]) => ({
id,
'min (m³/h)': toH(m.predictFlow.currentFxyYMin),
'max (m³/h)': toH(m.predictFlow.currentFxyYMax),
'BEP (m³/h)': toH(m.predictFlow.currentFxyYMin + (m.predictFlow.currentFxyYMax - m.predictFlow.currentFxyYMin) * m.NCog),
NCog: +m.NCog.toFixed(3),
})));
const minQ = Math.max(...Object.values(machines).map(m => m.predictFlow.currentFxyYMin));
const maxQ = Object.values(machines).reduce((s, m) => s + m.predictFlow.currentFxyYMax, 0);
const demandPcts = [0.10, 0.25, 0.50, 0.75, 0.90];
const rows = [];
for (const pct of demandPcts) {
const Qd = minQ + (maxQ - minQ) * pct;
// Reset all machines to idle, re-inject pressure
for (const m of Object.values(machines)) {
if (m.state.getCurrentState() !== 'idle') await m.handleInput('parent', 'execSequence', 'shutdown');
injectPressure(m);
}
// Run machineGroupControl optimalControl with absolute scaling
mg.setMode('optimalcontrol');
mg.setScaling('absolute');
mg.calcAbsoluteTotals();
mg.calcDynamicTotals();
await mg.handleInput('parent', Qd);
// Read ACTUAL per-pump state (not the MGC summary which may be stale)
let mgcPower = 0, mgcFlow = 0;
const mgcCombo = [];
const mgcDist = {};
for (const [id, m] of Object.entries(machines)) {
const state = m.state.getCurrentState();
const flow = m.measurements.type('flow').variant('predicted').position('downstream').getCurrentValue(CANON_FLOW) || 0;
const power = m.measurements.type('power').variant('predicted').position('atequipment').getCurrentValue(CANON_POWER) || 0;
mgcDist[id] = { flow, power, state };
if (state === 'operational' || state === 'warmingup' || state === 'accelerating') {
mgcCombo.push(id);
mgcPower += power;
mgcFlow += flow;
}
}
// Naive baselines
const sp = spillover(machines, Qd);
const ea = equalAllOn(machines, Qd);
const best = Math.min(mgcPower, sp.power, ea.power);
const delta = (v) => best > 0 ? `${(((v - best) / best) * 100).toFixed(1)}%` : '';
rows.push({
demand: `${(pct * 100)}%`,
'Qd (m³/h)': toH(Qd),
'MGC kW': +(mgcPower / 1000).toFixed(1),
'MGC flow': toH(mgcFlow),
'MGC pumps': mgcCombo.join('+') || 'none',
'Spill kW': +(sp.power / 1000).toFixed(1),
'Spill flow': toH(sp.flow),
'Spill pumps': sp.combo.join('+'),
'EqAll kW': +(ea.power / 1000).toFixed(1),
'EqAll flow': toH(ea.flow),
'MGC Δ': delta(mgcPower),
'Spill Δ': delta(sp.power),
'EqAll Δ': delta(ea.power),
});
}
console.log('\n=== POWER + FLOW COMPARISON (★ = best, all must deliver Qd) ===');
console.table(rows);
// Per-pump detail at each demand level
for (const pct of demandPcts) {
const Qd = minQ + (maxQ - minQ) * pct;
for (const m of Object.values(machines)) {
if (m.state.getCurrentState() !== 'idle') await m.handleInput('parent', 'execSequence', 'shutdown');
injectPressure(m);
}
mg.setMode('optimalcontrol');
mg.setScaling('absolute');
mg.calcAbsoluteTotals();
mg.calcDynamicTotals();
await mg.handleInput('parent', Qd);
const detail = Object.entries(machines).map(([id, m]) => {
const state = m.state.getCurrentState();
const flow = m.measurements.type('flow').variant('predicted').position('downstream').getCurrentValue(CANON_FLOW) || 0;
const power = m.measurements.type('power').variant('predicted').position('atequipment').getCurrentValue(CANON_POWER) || 0;
return {
pump: id,
state,
'flow (m³/h)': toH(flow),
'power (kW)': +(power / 1000).toFixed(1),
};
});
console.log(`\n--- MGC per-pump @ ${(pct*100)}% (${toH(Qd)} m³/h) ---`);
console.table(detail);
}
// Flow verification on naive strategies
for (const pct of demandPcts) {
const Qd = minQ + (maxQ - minQ) * pct;
const sp = spillover(machines, Qd);
const ea = equalAllOn(machines, Qd);
assert.ok(Math.abs(sp.flow - Qd) < Qd * 0.005, `Spillover flow mismatch at ${(pct*100)}%`);
assert.ok(Math.abs(ea.flow - Qd) < Qd * 0.005, `Equal-all flow mismatch at ${(pct*100)}%`);
}
});

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/**
* Group Distribution Strategy Comparison Test
*
* Compares three flow distribution strategies for a group of pumps:
* 1. NCog/BEP-Gravitation (slope-weighted — favours pumps with flatter power curves)
* 2. Equal distribution (same flow to every pump)
* 3. Spillover (fill smallest pump first, overflow to next)
*
* For variable-speed centrifugal pumps, specific flow (Q/P) is monotonically
* decreasing per pump (affinity laws: P ∝ Q³), so NCog = 0 for all pumps.
* The real optimization value comes from the BEP-Gravitation algorithm's
* slope-based redistribution, which IS sensitive to curve shape differences.
*
* These tests verify that:
* - Asymmetric pumps produce different power slopes (the basis for optimization)
* - BEP-Gravitation uses less total power than naive strategies for mixed pumps
* - Equal pumps receive equal treatment under all strategies
* - Spillover creates a visibly different distribution than BEP-weighted
*/
const test = require('node:test');
const assert = require('node:assert/strict');
const MachineGroup = require('../../src/specificClass');
const Machine = require('../../../rotatingMachine/src/specificClass');
const baseCurve = require('../../../generalFunctions/datasets/assetData/curves/hidrostal-H05K-S03R.json');
/* ---- helpers ---- */
function deepClone(obj) { return JSON.parse(JSON.stringify(obj)); }
function distortSeries(series, scale = 1, tilt = 0) {
const last = series.length - 1;
return series.map((v, i) => {
const gradient = last === 0 ? 0 : i / last - 0.5;
return Math.max(v * scale * (1 + tilt * gradient), 0);
});
}
function createSyntheticCurve(mods) {
const { flowScale = 1, powerScale = 1, flowTilt = 0, powerTilt = 0 } = mods;
const curve = deepClone(baseCurve);
Object.values(curve.nq).forEach(s => { s.y = distortSeries(s.y, flowScale, flowTilt); });
Object.values(curve.np).forEach(s => { s.y = distortSeries(s.y, powerScale, powerTilt); });
return curve;
}
const stateConfig = {
time: { starting: 0, warmingup: 0, stopping: 0, coolingdown: 0 },
movement: { speed: 1200, mode: 'staticspeed', maxSpeed: 1800 }
};
function createMachineConfig(id, label) {
return {
general: { logging: { enabled: false, logLevel: 'error' }, name: label, id, unit: 'm3/h' },
functionality: { softwareType: 'machine', role: 'rotationaldevicecontroller' },
asset: { category: 'pump', type: 'centrifugal', model: 'hidrostal-H05K-S03R', supplier: 'hidrostal' },
mode: {
current: 'auto',
allowedActions: { auto: ['execsequence', 'execmovement', 'flowmovement', 'statuscheck'] },
allowedSources: { auto: ['parent', 'GUI'] }
},
sequences: {
startup: ['starting', 'warmingup', 'operational'],
shutdown: ['stopping', 'coolingdown', 'idle'],
emergencystop: ['emergencystop', 'off'],
}
};
}
function createGroupConfig(name) {
return {
general: { logging: { enabled: false, logLevel: 'error' }, name },
functionality: { softwareType: 'machinegroup', role: 'groupcontroller' },
scaling: { current: 'normalized' },
mode: { current: 'optimalcontrol' }
};
}
/**
* Bootstrap with differential pressure (upstream + downstream) so the predict
* engine resolves a realistic fDimension and calcEfficiencyCurve produces
* a proper BEP peak — not a monotonic Q/P curve.
*/
function bootstrapGroup(name, machineSpecs, diffMbar, upstreamMbar = 800) {
const mg = new MachineGroup(createGroupConfig(name));
const machines = {};
for (const spec of machineSpecs) {
const m = new Machine(createMachineConfig(spec.id, spec.label), stateConfig);
if (spec.curveMods) m.updateCurve(createSyntheticCurve(spec.curveMods));
// Set BOTH upstream and downstream so getMeasuredPressure computes differential
m.updateMeasuredPressure(upstreamMbar, 'upstream', {
timestamp: Date.now(), unit: 'mbar', childName: `pt-up-${spec.id}`, childId: `pt-up-${spec.id}`
});
m.updateMeasuredPressure(upstreamMbar + diffMbar, 'downstream', {
timestamp: Date.now(), unit: 'mbar', childName: `pt-dn-${spec.id}`, childId: `pt-dn-${spec.id}`
});
mg.childRegistrationUtils.registerChild(m, 'downstream');
machines[spec.id] = m;
}
return { mg, machines };
}
/** Distribute flow weighted by each machine's NCog (BEP position). */
function distributeByNCog(machines, Qd) {
const entries = Object.entries(machines);
let totalNCog = entries.reduce((s, [, m]) => s + (m.NCog || 0), 0);
const distribution = {};
for (const [id, m] of entries) {
const min = m.predictFlow.currentFxyYMin;
const max = m.predictFlow.currentFxyYMax;
const flow = totalNCog > 0
? ((m.NCog || 0) / totalNCog) * Qd
: Qd / entries.length;
distribution[id] = Math.min(max, Math.max(min, flow));
}
let totalPower = 0;
for (const [id, m] of entries) {
totalPower += m.inputFlowCalcPower(distribution[id]);
}
return { distribution, totalPower };
}
/** Compute power at a given flow for a machine using its inverse curve. */
function powerAtFlow(machine, flow) {
return machine.inputFlowCalcPower(flow);
}
/** Distribute by slope-weighting: flatter dP/dQ curves attract more flow. */
function distributeBySlopeWeight(machines, Qd) {
const entries = Object.entries(machines);
// Estimate slope (dP/dQ) at midpoint for each machine
const pumpInfos = entries.map(([id, m]) => {
const min = m.predictFlow.currentFxyYMin;
const max = m.predictFlow.currentFxyYMax;
const mid = (min + max) / 2;
const delta = Math.max((max - min) * 0.05, 0.001);
const pMid = powerAtFlow(m, mid);
const pRight = powerAtFlow(m, Math.min(max, mid + delta));
const slope = Math.abs((pRight - pMid) / delta);
return { id, m, min, max, slope: Math.max(slope, 1e-6) };
});
// Weight = 1/slope: flatter curves get more flow
const totalWeight = pumpInfos.reduce((s, p) => s + (1 / p.slope), 0);
const distribution = {};
let totalPower = 0;
for (const p of pumpInfos) {
const weight = (1 / p.slope) / totalWeight;
const flow = Math.min(p.max, Math.max(p.min, Qd * weight));
distribution[p.id] = flow;
totalPower += powerAtFlow(p.m, flow);
}
return { distribution, totalPower };
}
/** Distribute equally. */
function distributeEqual(machines, Qd) {
const entries = Object.entries(machines);
const flowEach = Qd / entries.length;
const distribution = {};
let totalPower = 0;
for (const [id, m] of entries) {
const min = m.predictFlow.currentFxyYMin;
const max = m.predictFlow.currentFxyYMax;
const clamped = Math.min(max, Math.max(min, flowEach));
distribution[id] = clamped;
totalPower += powerAtFlow(m, clamped);
}
return { distribution, totalPower };
}
/** Spillover: fill smallest pump to max first, then overflow to next. */
function distributeSpillover(machines, Qd) {
const entries = Object.entries(machines)
.sort(([, a], [, b]) => a.predictFlow.currentFxyYMax - b.predictFlow.currentFxyYMax);
let remaining = Qd;
const distribution = {};
let totalPower = 0;
for (const [id, m] of entries) {
const min = m.predictFlow.currentFxyYMin;
const max = m.predictFlow.currentFxyYMax;
const assigned = Math.min(max, Math.max(min, remaining));
distribution[id] = assigned;
remaining = Math.max(0, remaining - assigned);
}
for (const [id, m] of entries) {
totalPower += powerAtFlow(m, distribution[id]);
}
return { distribution, totalPower };
}
/* ---- tests ---- */
test('NCog is meaningful (0 < NCog ≤ 1) with proper differential pressure', () => {
const { machines } = bootstrapGroup('ncog-basic', [
{ id: 'A', label: 'pump-A', curveMods: { flowScale: 1, powerScale: 1 } },
], 400); // 400 mbar differential
const m = machines['A'];
assert.ok(Number.isFinite(m.NCog), `NCog should be finite, got ${m.NCog}`);
assert.ok(m.NCog > 0 && m.NCog <= 1, `NCog should be in (0,1], got ${m.NCog.toFixed(4)}`);
assert.ok(m.cog > 0, `cog (peak specific flow) should be positive, got ${m.cog}`);
assert.ok(m.cogIndex > 0, `BEP should not be at index 0 (that means monotonic Q/P with no real peak)`);
});
test('different curve shapes produce different NCog at same pressure', () => {
// powerTilt shifts the BEP position: positive tilt makes power steeper at high flow
// (BEP moves left), negative tilt makes it flatter at high flow (BEP moves right)
const { machines } = bootstrapGroup('ncog-shapes', [
{ id: 'early', label: 'early-BEP', curveMods: { flowScale: 1, powerScale: 1, powerTilt: 0.4 } },
{ id: 'late', label: 'late-BEP', curveMods: { flowScale: 1, powerScale: 1, powerTilt: -0.3 } },
], 400);
const ncogEarly = machines['early'].NCog;
const ncogLate = machines['late'].NCog;
assert.ok(ncogEarly > 0, `Early BEP NCog should be > 0, got ${ncogEarly.toFixed(4)}`);
assert.ok(ncogLate > 0, `Late BEP NCog should be > 0, got ${ncogLate.toFixed(4)}`);
assert.ok(
ncogLate > ncogEarly,
`Late BEP pump should have higher NCog (BEP further into flow range). ` +
`early=${ncogEarly.toFixed(4)}, late=${ncogLate.toFixed(4)}`
);
});
test('NCog-weighted distribution differs from equal split for pumps with different BEPs', () => {
// Two pumps with different BEP positions (via powerTilt)
const { machines } = bootstrapGroup('ncog-vs-equal', [
{ id: 'early', label: 'early-BEP', curveMods: { flowScale: 1, powerScale: 1, powerTilt: 0.4 } },
{ id: 'late', label: 'late-BEP', curveMods: { flowScale: 1, powerScale: 1, powerTilt: -0.3 } },
], 400);
const ncogA = machines['early'].NCog;
const ncogB = machines['late'].NCog;
assert.ok(ncogA > 0 && ncogB > 0, `Both NCog should be > 0 (early=${ncogA.toFixed(3)}, late=${ncogB.toFixed(3)})`);
assert.ok(ncogA !== ncogB, 'NCog values should differ');
const totalMax = machines['early'].predictFlow.currentFxyYMax + machines['late'].predictFlow.currentFxyYMax;
const Qd = totalMax * 0.5;
const ncogResult = distributeByNCog(machines, Qd);
const equalResult = distributeEqual(machines, Qd);
// NCog distributes proportionally to BEP position — late-BEP pump gets more flow
assert.ok(
ncogResult.distribution['late'] > ncogResult.distribution['early'],
`Late-BEP pump should get more flow under NCog. ` +
`early=${ncogResult.distribution['early'].toFixed(2)}, late=${ncogResult.distribution['late'].toFixed(2)}`
);
// Equal split gives same flow to both (they have same flow range, just different BEPs)
const equalDiff = Math.abs(equalResult.distribution['early'] - equalResult.distribution['late']);
const ncogDiff = Math.abs(ncogResult.distribution['early'] - ncogResult.distribution['late']);
assert.ok(
ncogDiff > equalDiff + Qd * 0.01,
`NCog distribution should be more asymmetric than equal split`
);
});
test('asymmetric pumps have different power curve slopes', () => {
// A pump with low powerScale has a flatter power curve
const { machines } = bootstrapGroup('slope-check', [
{ id: 'flat', label: 'flat-power', curveMods: { flowScale: 1.2, powerScale: 0.7, flowTilt: 0.1 } },
{ id: 'steep', label: 'steep-power', curveMods: { flowScale: 0.8, powerScale: 1.4, flowTilt: -0.05 } },
], 400);
// Compute slope at midpoint of each machine's range
const slopes = {};
for (const [id, m] of Object.entries(machines)) {
const mid = (m.predictFlow.currentFxyYMin + m.predictFlow.currentFxyYMax) / 2;
const delta = (m.predictFlow.currentFxyYMax - m.predictFlow.currentFxyYMin) * 0.05;
const pMid = powerAtFlow(m, mid);
const pRight = powerAtFlow(m, mid + delta);
slopes[id] = (pRight - pMid) / delta;
}
assert.ok(slopes['flat'] > 0 && slopes['steep'] > 0, 'Both slopes should be positive');
assert.ok(
slopes['steep'] > slopes['flat'] * 1.3,
`Steep pump should have notably higher slope. flat=${slopes['flat'].toFixed(0)}, steep=${slopes['steep'].toFixed(0)}`
);
});
test('slope-weighted distribution routes more flow to flatter pump', () => {
const { machines } = bootstrapGroup('slope-routing', [
{ id: 'flat', label: 'flat-power', curveMods: { flowScale: 1.2, powerScale: 0.7 } },
{ id: 'steep', label: 'steep-power', curveMods: { flowScale: 0.8, powerScale: 1.4 } },
], 400);
const totalMax = machines['flat'].predictFlow.currentFxyYMax + machines['steep'].predictFlow.currentFxyYMax;
const Qd = totalMax * 0.5;
const slopeResult = distributeBySlopeWeight(machines, Qd);
assert.ok(
slopeResult.distribution['flat'] > slopeResult.distribution['steep'],
`Flat pump should get more flow. flat=${slopeResult.distribution['flat'].toFixed(2)}, steep=${slopeResult.distribution['steep'].toFixed(2)}`
);
});
test('slope-weighted uses less power than equal split for asymmetric pumps', () => {
const { machines } = bootstrapGroup('power-compare', [
{ id: 'eff', label: 'efficient', curveMods: { flowScale: 1.2, powerScale: 0.7, flowTilt: 0.12 } },
{ id: 'std', label: 'standard', curveMods: { flowScale: 1, powerScale: 1 } },
], 400);
const totalMax = machines['eff'].predictFlow.currentFxyYMax + machines['std'].predictFlow.currentFxyYMax;
const demandLevels = [0.3, 0.5, 0.7].map(p => {
const min = Math.max(machines['eff'].predictFlow.currentFxyYMin, machines['std'].predictFlow.currentFxyYMin);
return min + (totalMax - min) * p;
});
let slopeWins = 0;
const results = [];
for (const Qd of demandLevels) {
const slopeResult = distributeBySlopeWeight(machines, Qd);
const equalResult = distributeEqual(machines, Qd);
const spillResult = distributeSpillover(machines, Qd);
results.push({
demand: Qd,
slopePower: slopeResult.totalPower,
equalPower: equalResult.totalPower,
spillPower: spillResult.totalPower,
});
if (slopeResult.totalPower <= equalResult.totalPower + 1) slopeWins++;
}
assert.ok(
slopeWins >= 2,
`Slope-weighted should use ≤ power than equal in ≥ 2/3 cases.\n` +
results.map(r =>
` Qd=${r.demand.toFixed(1)}: slope=${r.slopePower.toFixed(1)}W, equal=${r.equalPower.toFixed(1)}W, spill=${r.spillPower.toFixed(1)}W`
).join('\n')
);
});
test('spillover produces visibly different distribution than slope-weighted for mixed sizes', () => {
const { machines } = bootstrapGroup('spillover-vs-slope', [
{ id: 'small', label: 'small-pump', curveMods: { flowScale: 0.6, powerScale: 0.55 } },
{ id: 'large', label: 'large-pump', curveMods: { flowScale: 1.5, powerScale: 1.2 } },
], 400);
const totalMax = machines['small'].predictFlow.currentFxyYMax + machines['large'].predictFlow.currentFxyYMax;
const Qd = totalMax * 0.5;
const slopeResult = distributeBySlopeWeight(machines, Qd);
const spillResult = distributeSpillover(machines, Qd);
// Spillover fills the small pump first, slope-weight distributes by curve shape
const slopeDiff = Math.abs(slopeResult.distribution['small'] - spillResult.distribution['small']);
const percentDiff = (slopeDiff / Qd) * 100;
assert.ok(
percentDiff > 1,
`Strategies should produce different distributions. ` +
`Slope small=${slopeResult.distribution['small'].toFixed(2)}, ` +
`Spill small=${spillResult.distribution['small'].toFixed(2)} (${percentDiff.toFixed(1)}% diff)`
);
});
test('equal pumps get equal flow under all strategies', () => {
const { machines } = bootstrapGroup('equal-pumps', [
{ id: 'A', label: 'pump-A', curveMods: { flowScale: 1, powerScale: 1 } },
{ id: 'B', label: 'pump-B', curveMods: { flowScale: 1, powerScale: 1 } },
], 400);
const totalMax = machines['A'].predictFlow.currentFxyYMax + machines['B'].predictFlow.currentFxyYMax;
const Qd = totalMax * 0.6;
const slopeResult = distributeBySlopeWeight(machines, Qd);
const equalResult = distributeEqual(machines, Qd);
const tolerance = Qd * 0.01;
assert.ok(
Math.abs(slopeResult.distribution['A'] - slopeResult.distribution['B']) < tolerance,
`Slope-weighted should split equally for identical pumps. A=${slopeResult.distribution['A'].toFixed(2)}, B=${slopeResult.distribution['B'].toFixed(2)}`
);
assert.ok(
Math.abs(equalResult.distribution['A'] - equalResult.distribution['B']) < tolerance,
`Equal should split equally. A=${equalResult.distribution['A'].toFixed(2)}, B=${equalResult.distribution['B'].toFixed(2)}`
);
// Power should be identical too
assert.ok(
Math.abs(slopeResult.totalPower - equalResult.totalPower) < 1,
`Equal pumps should produce same total power under any strategy`
);
});
test('full MGC optimalControl uses ≤ power than priorityControl for mixed pumps', async () => {
const { mg, machines } = bootstrapGroup('mgc-full', [
{ id: 'eff', label: 'efficient', curveMods: { flowScale: 1.2, powerScale: 0.7, flowTilt: 0.1 } },
{ id: 'std', label: 'standard', curveMods: { flowScale: 1, powerScale: 1 } },
{ id: 'weak', label: 'weak', curveMods: { flowScale: 0.8, powerScale: 1.3, flowTilt: -0.08 } },
], 400);
for (const m of Object.values(machines)) {
await m.handleInput('parent', 'execSequence', 'startup');
}
// Run optimalControl
mg.setMode('optimalcontrol');
mg.setScaling('normalized');
await mg.handleInput('parent', 50, Infinity);
const optPower = mg.measurements.type('power').variant('predicted').position('atequipment').getCurrentValue() || 0;
const optFlow = mg.measurements.type('flow').variant('predicted').position('atequipment').getCurrentValue() || 0;
// Reset machines
for (const m of Object.values(machines)) {
await m.handleInput('parent', 'execSequence', 'shutdown');
await m.handleInput('parent', 'execSequence', 'startup');
}
// Run priorityControl
mg.setMode('prioritycontrol');
await mg.handleInput('parent', 50, Infinity, ['eff', 'std', 'weak']);
const prioPower = mg.measurements.type('power').variant('predicted').position('atequipment').getCurrentValue() || 0;
const prioFlow = mg.measurements.type('flow').variant('predicted').position('atequipment').getCurrentValue() || 0;
assert.ok(optFlow > 0, `Optimal should deliver flow, got ${optFlow}`);
assert.ok(prioFlow > 0, `Priority should deliver flow, got ${prioFlow}`);
// Compare efficiency (flow per unit power)
const optEff = optPower > 0 ? optFlow / optPower : 0;
const prioEff = prioPower > 0 ? prioFlow / prioPower : 0;
assert.ok(
optEff >= prioEff * 0.95,
`Optimal efficiency should be ≥ priority (within 5% tolerance). ` +
`Opt: ${optFlow.toFixed(1)}/${optPower.toFixed(1)}=${optEff.toFixed(6)} | ` +
`Prio: ${prioFlow.toFixed(1)}/${prioPower.toFixed(1)}=${prioEff.toFixed(6)}`
);
});

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const test = require('node:test');
const assert = require('node:assert/strict');
const fs = require('node:fs');
const path = require('node:path');
const dir = path.resolve(__dirname, '../../examples');
function loadJson(file) {
return JSON.parse(fs.readFileSync(path.join(dir, file), 'utf8'));
}
test('examples package exists for machineGroupControl', () => {
for (const file of ['README.md', 'basic.flow.json', 'integration.flow.json', 'edge.flow.json']) {
assert.equal(fs.existsSync(path.join(dir, file)), true, file + ' missing');
}
});
test('example flows are parseable arrays for machineGroupControl', () => {
for (const file of ['basic.flow.json', 'integration.flow.json', 'edge.flow.json']) {
const parsed = loadJson(file);
assert.equal(Array.isArray(parsed), true);
}
});