/** * @file test_fuel_map.cpp * * Created on: Nov 6, 2013 * Author: Andrey Belomutskiy, (c) 2012-2013 */ #include "test_fuel_map.h" #include "main.h" #include "engine_configuration.h" #include "fuel_math.h" #include "trigger_structure.h" #include "allsensors.h" #include "engine_math.h" #include "OutputSignalList.h" #include "ec2.h" #include "trigger_decoder.h" #include "engine_test_helper.h" #include "efiGpio.h" extern float testMafValue; void testFuelMap(void) { printf("*************************************************** testFuelMap\r\n"); EngineTestHelper eth(FORD_ASPIRE_1996); for (int k = 0; k < FUEL_LOAD_COUNT; k++) { for (int r = 0; r < FUEL_RPM_COUNT; r++) { eth.engine.engineConfiguration->fuelTable[k][r] = k * 200 + r; } } for (int i = 0; i < FUEL_LOAD_COUNT; i++) eth.engine.engineConfiguration->fuelLoadBins[i] = i; for (int i = 0; i < FUEL_RPM_COUNT; i++) eth.engine.engineConfiguration->fuelRpmBins[i] = i; assertEqualsM("base fuel table", 1005, getBaseTableFuel(eth.engine.engineConfiguration, 5, 5)); printf("*************************************************** initThermistors\r\n"); Engine *engine = ð.engine; engine_configuration_s *engineConfiguration = engine->engineConfiguration; initThermistors(engine); printf("*** getInjectorLag\r\n"); assertEquals(1.0, getInjectorLag(12 PASS_ENGINE_PARAMETER)); eth.engine.engineConfiguration->injectorLag = 0.5; for (int i = 0; i < VBAT_INJECTOR_CURVE_SIZE; i++) { eth.engine.engineConfiguration->battInjectorLagCorrBins[i] = i; eth.engine.engineConfiguration->battInjectorLagCorr[i] = 2 * i; } // because all the correction tables are zero printf("*************************************************** getRunningFuel 1\r\n"); float baseFuel = getBaseTableFuel(eth.engine.engineConfiguration, 5, getEngineLoadT(PASS_ENGINE_PARAMETER_F)); assertEqualsM("base fuel", 5.05, getRunningFuel(baseFuel, 5 PASS_ENGINE_PARAMETER)); printf("*************************************************** setting IAT table\r\n"); for (int i = 0; i < IAT_CURVE_SIZE; i++) { eth.engine.engineConfiguration->iatFuelCorrBins[i] = i; eth.engine.engineConfiguration->iatFuelCorr[i] = 2 * i; } eth.engine.engineConfiguration->iatFuelCorr[0] = 2; printf("*************************************************** setting CLT table\r\n"); for (int i = 0; i < CLT_CURVE_SIZE; i++) { eth.engine.engineConfiguration->cltFuelCorrBins[i] = i; eth.engine.engineConfiguration->cltFuelCorr[i] = 1; } eth.engine.engineConfiguration->injectorLag = 0; assertEquals(NAN, getIntakeAirTemperature(ð.engine)); float iatCorrection = getIatCorrection(-KELV PASS_ENGINE_PARAMETER); assertEqualsM("IAT", 2, iatCorrection); float cltCorrection = getCltCorrection(getCoolantTemperature(ð.engine) PASS_ENGINE_PARAMETER); assertEqualsM("CLT", 1, cltCorrection); float injectorLag = getInjectorLag(getVBatt(engineConfiguration) PASS_ENGINE_PARAMETER); assertEquals(0, injectorLag); testMafValue = 5; // 1005 * 2 for IAT correction printf("*************************************************** getRunningFuel 2\r\n"); baseFuel = getBaseTableFuel(eth.engine.engineConfiguration, 5, getEngineLoadT(PASS_ENGINE_PARAMETER_F)); assertEqualsM("v1", 30150, getRunningFuel(baseFuel, 5 PASS_ENGINE_PARAMETER)); testMafValue = 0; engineConfiguration->crankingSettings.baseCrankingFuel = 4; printf("*************************************************** getStartingFuel\r\n"); // NAN in case we have issues with the CLT sensor assertEqualsM("getStartingFuel nan", 4, getCrankingFuel3(engineConfiguration, NAN, 0)); assertEqualsM("getStartingFuel#1", 23.7333, getCrankingFuel3(engineConfiguration, 0, 4)); assertEqualsM("getStartingFuel#2", 18.0419, getCrankingFuel3(engineConfiguration, 8, 15)); assertEqualsM("getStartingFuel#3", 11.2000, getCrankingFuel3(engineConfiguration, 70, 0)); assertEqualsM("getStartingFuel#3", 5.6000, getCrankingFuel3(engineConfiguration, 70, 50)); } extern engine_configuration_s *engineConfiguration; extern engine_configuration2_s *engineConfiguration2; static void confgiureFordAspireTriggerShape(trigger_shape_s * s) { s->reset(FOUR_STROKE_CAM_SENSOR); s->addEvent(53.747, T_SECONDARY, TV_HIGH); s->addEvent(121.90, T_SECONDARY, TV_LOW); s->addEvent(232.76, T_SECONDARY, TV_HIGH); s->addEvent(300.54, T_SECONDARY, TV_LOW); s->addEvent(360, T_PRIMARY, TV_HIGH); s->addEvent(409.8412, T_SECONDARY, TV_HIGH); s->addEvent(478.6505, T_SECONDARY, TV_LOW); s->addEvent(588.045, T_SECONDARY, TV_HIGH); s->addEvent(657.03, T_SECONDARY, TV_LOW); s->addEvent(720, T_PRIMARY, TV_LOW); assertEquals(53.747 / 720, s->wave.getSwitchTime(0)); assertEqualsM("@0", 1, s->wave.getChannelState(1, 0)); assertEqualsM("@0", 1, s->wave.getChannelState(1, 0)); assertEqualsM("@1", 0, s->wave.getChannelState(0, 1)); assertEqualsM("@1", 0, s->wave.getChannelState(1, 1)); assertEqualsM("@2", 0, s->wave.getChannelState(0, 2)); assertEqualsM("@2", 1, s->wave.getChannelState(1, 2)); assertEqualsM("@3", 0, s->wave.getChannelState(0, 3)); assertEqualsM("@3", 0, s->wave.getChannelState(1, 3)); assertEqualsM("@4", 1, s->wave.getChannelState(0, 4)); assertEqualsM("@5", 1, s->wave.getChannelState(1, 5)); assertEqualsM("@8", 0, s->wave.getChannelState(1, 8)); assertEquals(121.90 / 720, s->wave.getSwitchTime(1)); assertEquals(657.03 / 720, s->wave.getSwitchTime(8)); assertEqualsM("expecting 0", 0, s->wave.findAngleMatch(53.747 / 720.0, s->getSize())); assertEqualsM("expecting not found", -1, s->wave.findAngleMatch(53 / 720.0, s->getSize())); assertEquals(7, s->wave.findAngleMatch(588.045 / 720.0, s->getSize())); assertEqualsM("expecting 0", 0, s->wave.waveIndertionAngle(23.747 / 720.0, s->getSize())); assertEqualsM("expecting 1", 1, s->wave.waveIndertionAngle(63.747 / 720.0, s->getSize())); } static ActuatorEventList ae; void testAngleResolver(void) { printf("*************************************************** testAngleResolver\r\n"); EngineTestHelper eth(FORD_ASPIRE_1996); Engine *engine = ð.engine; engine_configuration_s *engineConfiguration = eth.engine.engineConfiguration; engineConfiguration->globalTriggerAngleOffset = 175; assertTrue(engine->engineConfiguration2!=NULL); trigger_shape_s * ts = &engine->triggerShape; confgiureFordAspireTriggerShape(ts); ts->calculateTriggerSynchPoint(engineConfiguration, engine); assertEqualsM("index 2", 228.0450, ts->eventAngles[3]); // this angle is relation to synch point assertEqualsM("time 2", 0.3233, ts->wave.getSwitchTime(2)); assertEqualsM("index 5", 413.7470, ts->eventAngles[6]); assertEqualsM("time 5", 0.5692, ts->wave.getSwitchTime(5)); assertEquals(4, ts->getTriggerShapeSynchPointIndex()); assertEqualsM("shape size", 10, ts->getSize()); OutputSignalList list; ae.resetEventList(); printf("*************************************************** testAngleResolver 0\r\n"); findTriggerPosition(&ae.getNextActuatorEvent()->position, 53 - 175 PASS_ENGINE_PARAMETER); assertEqualsM("size", 1, ae.size); assertEquals(1, ae.events[0].position.eventIndex); assertEquals(3.1588, ae.events[0].position.angleOffset); printf("*************************************************** testAngleResolver 2\r\n"); ae.resetEventList(); findTriggerPosition(&ae.getNextActuatorEvent()->position, 51 + 180 - 175 PASS_ENGINE_PARAMETER); assertEquals(2, ae.events[0].position.eventIndex); assertEquals(112.3495, ae.events[0].position.angleOffset); } void testPinHelper(void) { printf("*************************************************** testPinHelper\r\n"); assertEquals(0, getElectricalValue(0, OM_DEFAULT)); assertEquals(1, getElectricalValue(1, OM_DEFAULT)); assertEquals(0, getElectricalValue(1, OM_INVERTED)); assertEquals(1, getElectricalValue(0, OM_INVERTED)); }