#pragma once #include "rusefi_types.h" struct stft_cell_cfg_s { // % // offset 0 int8_t maxAdd; // % // offset 1 int8_t maxRemove; // Time constant for correction while in this cell: this sets responsiveness of the closed loop correction. A value of 5.0 means it will try to make most of the correction within 5 seconds, and a value of 1.0 will try to correct within 1 second. // sec // offset 2 scaled_channel timeConstant; }; static_assert(sizeof(stft_cell_cfg_s) == 4); struct stft_s { // Below this RPM, the idle region is active // RPM // offset 0 scaled_channel maxIdleRegionRpm; // Below this engine load, the overrun region is active // load // offset 1 uint8_t maxOverrunLoad; // Above this engine load, the power region is active // load // offset 2 uint8_t minPowerLoad; // When close to correct AFR, pause correction. This can improve stability by not changing the adjustment if the error is extremely small, but is not required. // % // offset 3 scaled_channel deadband; // Below this temperature, correction is disabled. // C // offset 4 int8_t minClt; // Below this AFR, correction is paused // afr // offset 5 scaled_channel minAfr; // Above this AFR, correction is paused // afr // offset 6 scaled_channel maxAfr; // Delay after starting the engine before beginning closed loop correction. // seconds // offset 7 uint8_t startupDelay; // offset 8 stft_cell_cfg_s cellCfgs[STFT_CELL_COUNT]; }; static_assert(sizeof(stft_s) == 24); struct pid_s { // offset 0 float pFactor; // offset 4 float iFactor; // offset 8 float dFactor; // Linear addition to PID logic // offset 12 int16_t offset; // PID dTime // ms // offset 14 int16_t periodMs; // Output Min Duty Cycle // offset 16 int16_t minValue; // Output Max Duty Cycle // offset 18 int16_t maxValue; }; static_assert(sizeof(pid_s) == 20); struct cranking_parameters_s { // Base mass of the per-cylinder fuel injected during cranking. This is then modified by the multipliers for CLT, IAT, TPS ect, to give the final cranking pulse width. // A reasonable starting point is 60mg per liter per cylinder. // ex: 2 liter 4 cyl = 500cc/cyl, so 30mg cranking fuel. // mg // offset 0 float baseFuel; // This sets the RPM limit below which the ECU will use cranking fuel and ignition logic, typically this is around 350-450rpm. // RPM // offset 4 int16_t rpm; // need 4 byte alignment // units // offset 6 uint8_t alignmentFill_at_6[2]; }; static_assert(sizeof(cranking_parameters_s) == 8); struct gppwm_channel { // Select a pin to use for PWM or on-off output. // offset 0 output_pin_e pin; // If an error (with a sensor, etc) is detected, this value is used instead of reading from the table. // This should be a safe value for whatever hardware is connected to prevent damage. // % // offset 2 uint8_t dutyIfError; // need 4 byte alignment // units // offset 3 uint8_t alignmentFill_at_3[1]; // Select a frequency to run PWM at. // Set this to 0hz to enable on-off mode. // hz // offset 4 uint16_t pwmFrequency; // Hysteresis: in on-off mode, turn the output on when the table value is above this duty. // % // offset 6 uint8_t onAboveDuty; // Hysteresis: in on-off mode, turn the output off when the table value is below this duty. // % // offset 7 uint8_t offBelowDuty; // Selects the Y axis to use for the table. // offset 8 gppwm_channel_e loadAxis; // Selects the X axis to use for the table. // offset 9 gppwm_channel_e rpmAxis; // load // offset 10 scaled_channel loadBins[GPPWM_LOAD_COUNT]; // RPM // offset 26 scaled_channel rpmBins[GPPWM_RPM_COUNT]; // duty // offset 42 scaled_channel table[GPPWM_RPM_COUNT][GPPWM_LOAD_COUNT]; // need 4 byte alignment // units // offset 106 uint8_t alignmentFill_at_106[2]; }; static_assert(sizeof(gppwm_channel) == 108); struct air_pressure_sensor_config_s { // kPa value at low volts // kpa // offset 0 float lowValue; // kPa value at high volts // kpa // offset 4 float highValue; // offset 8 air_pressure_sensor_type_e type; // offset 9 adc_channel_e hwChannel; // need 4 byte alignment // units // offset 10 uint8_t alignmentFill_at_10[2]; }; static_assert(sizeof(air_pressure_sensor_config_s) == 12); // @brief MAP averaging configuration struct MAP_sensor_config_s { // offset 0 float samplingAngleBins[MAP_ANGLE_SIZE]; // MAP averaging sampling start crank degree angle // deg // offset 32 float samplingAngle[MAP_ANGLE_SIZE]; // offset 64 float samplingWindowBins[MAP_WINDOW_SIZE]; // MAP averaging angle crank degree duration // deg // offset 96 float samplingWindow[MAP_WINDOW_SIZE]; // offset 128 air_pressure_sensor_config_s sensor; }; static_assert(sizeof(MAP_sensor_config_s) == 140); // @brief Thermistor known values struct thermistor_conf_s { // these values are in Celcius // *C // offset 0 scaled_channel tempC_1; // *C // offset 4 scaled_channel tempC_2; // *C // offset 8 scaled_channel tempC_3; // Ohm // offset 12 scaled_channel resistance_1; // Ohm // offset 16 scaled_channel resistance_2; // Ohm // offset 20 scaled_channel resistance_3; // Pull-up resistor value on your board // Ohm // offset 24 scaled_channel bias_resistor; }; static_assert(sizeof(thermistor_conf_s) == 28); // @brief Linear sensor interpolation struct linear_sensor_s { // offset 0 adc_channel_e hwChannel; // need 4 byte alignment // units // offset 1 uint8_t alignmentFill_at_1[3]; // volts // offset 4 float v1; // kPa // offset 8 float value1; // volts // offset 12 float v2; // kPa // offset 16 float value2; }; static_assert(sizeof(linear_sensor_s) == 20); // @brief Thermistor curve parameters struct ThermistorConf { // offset 0 thermistor_conf_s config; // offset 28 adc_channel_e adcChannel; // need 4 byte alignment // units // offset 29 uint8_t alignmentFill_at_29[3]; }; static_assert(sizeof(ThermistorConf) == 32); struct injector_s { // This is your injector flow at the fuel pressure used in the vehicle. cc/min, cubic centimetre per minute // By the way, g/s = 0.125997881 * (lb/hr) // g/s = 0.125997881 * (cc/min)/10.5 // g/s = 0.0119997981 * cc/min // cm3/min // offset 0 float flow; // volts // offset 4 scaled_channel battLagCorrBins[VBAT_INJECTOR_CURVE_SIZE]; // ms delay between injector open and close dead times // ms // offset 20 scaled_channel battLagCorr[VBAT_INJECTOR_CURVE_SIZE]; }; static_assert(sizeof(injector_s) == 36); // @brief Trigger wheel(s) configuration struct trigger_config_s { // https://github.com/rusefi/rusefi/wiki/All-Supported-Triggers // offset 0 trigger_type_e type; // number // offset 4 int customTotalToothCount; // number // offset 8 int customSkippedToothCount; }; static_assert(sizeof(trigger_config_s) == 12); struct afr_sensor_s { // offset 0 adc_channel_e hwChannel; // offset 1 adc_channel_e hwChannel2; // volts // offset 2 scaled_channel v1; // AFR // offset 4 scaled_channel value1; // volts // offset 6 scaled_channel v2; // AFR // offset 8 scaled_channel value2; // need 4 byte alignment // units // offset 10 uint8_t alignmentFill_at_10[2]; }; static_assert(sizeof(afr_sensor_s) == 12); struct idle_hardware_s { // Hz // offset 0 int solenoidFrequency; // offset 4 output_pin_e solenoidPin; // offset 6 Gpio stepperDirectionPin; // offset 8 Gpio stepperStepPin; // offset 10 pin_output_mode_e solenoidPinMode; // need 4 byte alignment // units // offset 11 uint8_t alignmentFill_at_11[1]; }; static_assert(sizeof(idle_hardware_s) == 12); struct dc_io { // offset 0 Gpio directionPin1; // offset 2 Gpio directionPin2; // Acts as EN pin in two-wire mode // offset 4 Gpio controlPin; // offset 6 Gpio disablePin; }; static_assert(sizeof(dc_io) == 8); struct vr_threshold_s { // rpm // offset 0 scaled_channel rpmBins[6]; // volts // offset 6 scaled_channel values[6]; // offset 12 Gpio pin; // need 4 byte alignment // units // offset 14 uint8_t alignmentFill_at_14[2]; }; static_assert(sizeof(vr_threshold_s) == 16); struct engine_configuration_s { // http://rusefi.com/wiki/index.php?title=Manual:Engine_Type // offset 0 engine_type_e engineType; // Disable sensor sniffer above this rpm // RPM // offset 4 uint16_t sensorSnifferRpmThreshold; // A secondary Rev limit engaged by the driver to help launch the vehicle faster // rpm // offset 6 uint16_t launchRpm; // rpm // offset 8 uint16_t rpmHardLimit; // Engine sniffer would be disabled above this rpm // RPM // offset 10 uint16_t engineSnifferRpmThreshold; // Disable multispark above this engine speed. // rpm // offset 12 scaled_channel multisparkMaxRpm; // Above this RPM, disable AC. Set to 0 to disable check. // rpm // offset 13 scaled_channel maxAcRpm; // Above this TPS, disable AC. Set to 0 to disable check. // % // offset 14 uint8_t maxAcTps; // Above this CLT, disable AC to prevent overheating the engine. Set to 0 to disable check. // deg C // offset 15 uint8_t maxAcClt; // RPM // offset 16 uint16_t knockNoiseRpmBins[ENGINE_NOISE_CURVE_SIZE]; // This parameter sets the latest that the last multispark can occur after the main ignition event. For example, if the ignition timing is 30 degrees BTDC, and this parameter is set to 45, no multispark will ever be fired after 15 degrees ATDC. // deg // offset 48 uint8_t multisparkMaxSparkingAngle; // Configures the maximum number of extra sparks to fire (does not include main spark) // count // offset 49 uint8_t multisparkMaxExtraSparkCount; // Single coil = distributor // Individual coils = one coil per cylinder (COP, coil-near-plug), requires sequential mode // Wasted spark = Fires pairs of cylinders together, either one coil per pair of cylinders or one coil per cylinder // Two distributors = A pair of distributors, found on some BMW, Toyota and other engines // offset 50 ignition_mode_e ignitionMode; // offset 51 can_nbc_e canNbcType; // offset 52 injector_s injector; // Does the vehicle have a turbo or supercharger? // offset 88 bit 0 bool isForcedInduction : 1 {}; // On some Ford and Toyota vehicles one of the throttle sensors is not linear on the full range, i.e. in the specific range of the positions we effectively have only one sensor. // offset 88 bit 1 bool useFordRedundantTps : 1 {}; // offset 88 bit 2 bool unused88b2 : 1 {}; // offset 88 bit 3 bool overrideTriggerGaps : 1 {}; // Turn on this fan when AC is on. // offset 88 bit 4 bool enableFan1WithAc : 1 {}; // Turn on this fan when AC is on. // offset 88 bit 5 bool enableFan2WithAc : 1 {}; // Inhibit operation of this fan while the engine is not running. // offset 88 bit 6 bool disableFan1WhenStopped : 1 {}; // Inhibit operation of this fan while the engine is not running. // offset 88 bit 7 bool disableFan2WhenStopped : 1 {}; // Enable secondary spark outputs that fire after the primary (rotaries, twin plug engines). // offset 88 bit 8 bool enableTrailingSparks : 1 {}; // TLE7209 uses two-wire mode. TLE9201 and VNH2SP30 do NOT use two wire mode. // offset 88 bit 9 bool etb_use_two_wires : 1 {}; // Subaru/BMW style where default valve position is somewhere in the middle. First solenoid opens it more while second can close it more than default position. // offset 88 bit 10 bool isDoubleSolenoidIdle : 1 {}; // offset 88 bit 11 bool useEeprom : 1 {}; // offset 88 bit 12 bool useTLE8888_cranking_hack : 1 {}; // offset 88 bit 13 bool kickStartCranking : 1 {}; // This uses separate ignition timing and VE tables not only for idle conditions, also during the postcranking-to-idle taper transition (See also afterCrankingIACtaperDuration). // offset 88 bit 14 bool useSeparateIdleTablesForCrankingTaper : 1 {}; // offset 88 bit 15 bool launchControlEnabled : 1 {}; // "Detect double trigger edges" // offset 88 bit 16 bool doNotFilterTriggerEdgeNoise : 1 {}; // offset 88 bit 17 bool antiLagEnabled : 1 {}; // For cranking either use the specified fixed base fuel mass, or use the normal running math (VE table). // offset 88 bit 18 bool useRunningMathForCranking : 1 {}; // offset 88 bit 19 bool useTLE8888_stepper : 1 {}; // offset 88 bit 20 bool usescriptTableForCanSniffingFiltering : 1 {}; // Print incoming and outgoing first bus CAN messages in rusEFI console // offset 88 bit 21 bool verboseCan : 1 {}; // Experimental setting that will cause a misfire // DO NOT ENABLE. // offset 88 bit 22 bool artificialTestMisfire : 1 {}; // On some Ford and Toyota vehicles one of the pedal sensors is not linear on the full range, i.e. in the specific range of the positions we effectively have only one sensor. // offset 88 bit 23 bool useFordRedundantPps : 1 {}; // offset 88 bit 24 bool cltSensorPulldown : 1 {}; // offset 88 bit 25 bool iatSensorPulldown : 1 {}; // offset 88 bit 26 bool allowIdenticalPps : 1 {}; // offset 88 bit 27 bool unusedBit_42_27 : 1 {}; // offset 88 bit 28 bool unusedBit_42_28 : 1 {}; // offset 88 bit 29 bool unusedBit_42_29 : 1 {}; // offset 88 bit 30 bool unusedBit_42_30 : 1 {}; // offset 88 bit 31 bool unusedBit_42_31 : 1 {}; // Closed throttle, 1 volt = 200 units // ADC // offset 92 int16_t tpsMin; // Full throttle, 1 volt = 200 units // ADC // offset 94 int16_t tpsMax; // TPS error detection: what throttle % is unrealistically low? // Also used for accelerator pedal error detection if so equiped. // % // offset 96 int16_t tpsErrorDetectionTooLow; // TPS error detection: what throttle % is unrealistically high? // Also used for accelerator pedal error detection if so equiped. // % // offset 98 int16_t tpsErrorDetectionTooHigh; // offset 100 cranking_parameters_s cranking; // Dwell duration while cranking // ms // offset 108 float ignitionDwellForCrankingMs; // Once engine speed passes this value, start reducing ETB angle. // rpm // offset 112 uint16_t etbRevLimitStart; // This far above 'Soft limiter start', fully close the throttle. At the bottom of the range, throttle control is normal. At the top of the range, the throttle is fully closed. // rpm // offset 114 uint16_t etbRevLimitRange; // offset 116 MAP_sensor_config_s map; // todo: merge with channel settings, use full-scale Thermistor here! // offset 256 ThermistorConf clt; // offset 288 ThermistorConf iat; // deg // offset 320 int launchTimingRetard; // We calculate knock band based of cylinderBore // Use this to override - kHz knock band override // kHz // offset 324 float knockBandCustom; // Engine displacement in litres // L // offset 328 scaled_channel displacement; // RPM // offset 330 uint16_t triggerSimulatorRpm; // Number of cylinder the engine has. // offset 332 uint32_t cylindersCount; // offset 336 firing_order_e firingOrder; // How many test bench pulses do you want // offset 337 uint8_t benchTestCount; // Duration of each test pulse // ms // offset 338 scaled_channel benchTestOnTime; // Cylinder diameter in mm. // mm // offset 340 float cylinderBore; // This setting controls which fuel quantity control algorithm is used. // Alpha-N means drive by TPS commonly only used for NA engines // Speed Density requires MAP sensor and is the default choice for may installs // MAF air charge is a cylinder filling based method that uses a mass air flow sensor. // offset 344 engine_load_mode_e fuelAlgorithm; // % // offset 345 uint8_t ALSMaxTPS; // offset 346 Gpio binarySerialTxPin; // offset 348 Gpio binarySerialRxPin; // This is the injection strategy during engine start. See Fuel/Injection settings for more detail. It is suggested to use "Simultaneous". // offset 350 injection_mode_e crankingInjectionMode; // This is where the fuel injection type is defined: "Simultaneous" means all injectors will fire together at once. "Sequential" fires the injectors on a per cylinder basis, which requires individually wired injectors. "Batched" will fire the injectors in groups. If your injectors are individually wired you will also need to enable "Two wire batch emulation". // offset 351 injection_mode_e injectionMode; // Minimum RPM to enable boost control. Use this to avoid solenoid noise at idle, and help spool in some cases. // offset 352 uint16_t boostControlMinRpm; // Minimum TPS to enable boost control. Use this to avoid solenoid noise at idle, and help spool in some cases. // offset 354 uint8_t boostControlMinTps; // Minimum MAP to enable boost control. Use this to avoid solenoid noise at idle, and help spool in some cases. // offset 355 uint8_t boostControlMinMap; // Dynamic uses the timing map to decide the ignition timing, Static timing fixes the timing to the value set below (only use for checking static timing with a timing light). // offset 356 timing_mode_e timingMode; // offset 357 adc_channel_e mafAdcChannel; // need 4 byte alignment // units // offset 358 uint8_t alignmentFill_at_358[2]; // Ignition advance angle used during engine cranking, 5-10 degrees will work as a base setting for most engines. // There is tapering towards running timing advance // deg // offset 360 angle_t crankingTimingAngle; // How many consecutive gap rations have to match expected ranges for sync to happen // count // offset 364 int8_t gapTrackingLengthOverride; // Above this speed, disable closed loop idle control. Set to 0 to disable (allow closed loop idle at any speed). // kph // offset 365 uint8_t maxIdleVss; // Expected oil pressure after starting the engine. If oil pressure does not reach this level within 5 seconds of engine start, fuel will be cut. Set to 0 to disable and always allow starting. // kPa // offset 366 uint16_t minOilPressureAfterStart; // This value is the ignition timing used when in 'fixed timing' mode, i.e. constant timing // This mode is useful when adjusting distributor location. // RPM // offset 368 angle_t fixedModeTiming; // Angle between Top Dead Center (TDC) and the first trigger event. // Positive value in case of synchnization point before TDC and negative in case of synchnization point after TDC // .Knowing this angle allows us to control timing and other angles in reference to TDC. // deg btdc // offset 372 angle_t globalTriggerAngleOffset; // Ratio/coefficient of input voltage dividers on your PCB. For example, use '2' if your board divides 5v into 2.5v. Use '1.66' if your board divides 5v into 3v. // coef // offset 376 float analogInputDividerCoefficient; // This is the ratio of the resistors for the battery voltage, measure the voltage at the battery and then adjust this number until the gauge matches the reading. // coef // offset 380 float vbattDividerCoeff; // Cooling fan turn-on temperature threshold, in Celsius // deg C // offset 384 uint8_t fanOnTemperature; // Cooling fan turn-off temperature threshold, in Celsius // deg C // offset 385 uint8_t fanOffTemperature; // offset 386 output_pin_e acrPin; // Number of revolutions per kilometer for the wheels your vehicle speed sensor is connected to. Use an online calculator to determine this based on your tire size. // revs/km // offset 388 float driveWheelRevPerKm; // CANbus thread period in ms // ms // offset 392 int canSleepPeriodMs; // index // offset 396 int byFirmwareVersion; // First throttle body, first sensor // offset 400 adc_channel_e tps1_1AdcChannel; // This is the processor input pin that the battery voltage circuit is connected to, if you are unsure of what pin to use, check the schematic that corresponds to your PCB. // offset 401 adc_channel_e vbattAdcChannel; // This is the processor pin that your fuel level sensor in connected to. This is a non standard input so will need to be user defined. // offset 402 adc_channel_e fuelLevelSensor; // Second throttle body, first sensor // offset 403 adc_channel_e tps2_1AdcChannel; // 0.1 is a good default value // x // offset 404 float idle_derivativeFilterLoss; // just a temporary solution // angle // offset 408 int trailingSparkAngle; // offset 412 trigger_config_s trigger; // Extra air taper amount // % // offset 424 float airByRpmTaper; // Duty cycle to use in case of a sensor failure. This duty cycle should produce the minimum possible amount of boost. This duty is also used in case any of the minimum RPM/TPS/MAP conditions are not met. // % // offset 428 uint8_t boostControlSafeDutyCycle; // Throttle pedal position first channel // offset 429 adc_channel_e throttlePedalPositionAdcChannel; // offset 430 pin_output_mode_e tle6240_csPinMode; // offset 431 uint8_t acrRevolutions; // coef // offset 432 float globalFuelCorrection; // volts // offset 436 float adcVcc; // Deg // offset 440 float mapCamDetectionAnglePosition; // Camshaft input could be used either just for engine phase detection if your trigger shape does not include cam sensor as 'primary' channel, or it could be used for Variable Valve timing on one of the camshafts. // offset 444 brain_input_pin_e camInputs[CAM_INPUTS_COUNT]; // offset 452 afr_sensor_s afr; // offset 464 Gpio tle6240_cs; // Throttle Pedal not pressed switch - used on some older vehicles like early Mazda Miata // offset 466 switch_input_pin_e throttlePedalUpPin; // offset 468 air_pressure_sensor_config_s baroSensor; // offset 480 idle_hardware_s idle; // Value between 0 and 100 used in Manual mode // % // offset 492 float manIdlePosition; // Ignition timing to remove when a knock event occurs. // % // offset 496 scaled_channel knockRetardAggression; // After a knock event, reapply timing at this rate. // deg/s // offset 497 scaled_channel knockRetardReapplyRate; // Select which cam is used for engine sync. Other cams will be used only for VVT measurement, but not engine sync. // offset 498 engineSyncCam_e engineSyncCam; // Set this so your vehicle speed signal is responsive, but not noisy. Larger value give smoother but slower response. // offset 499 uint8_t vssFilterReciprocal; // Number of turns of your vehicle speed sensor per turn of the wheels. For example if your sensor is on the transmission output, enter your axle/differential ratio. If you are using a hub-mounted sensor, enter a value of 1.0. // ratio // offset 500 scaled_channel vssGearRatio; // Number of pulses output per revolution of the shaft where your VSS is mounted. For example, GM applications of the T56 output 17 pulses per revolution of the transmission output shaft. // count // offset 502 uint8_t vssToothCount; // Override the Y axis (load) value used for only the Idle VE table. // Advanced users only: If you aren't sure you need this, you probably don't need this. // offset 503 ve_override_e idleVeOverrideMode; // offset 504 Gpio l9779_cs; // On-off O2 sensor heater control. 'ON' if engine is running, 'OFF' if stopped or cranking. // offset 506 output_pin_e o2heaterPin; // offset 508 output_pin_e injectionPins[MAX_CYLINDER_COUNT]; // offset 532 output_pin_e ignitionPins[MAX_CYLINDER_COUNT]; // offset 556 pin_output_mode_e injectionPinMode; // offset 557 pin_output_mode_e ignitionPinMode; // offset 558 output_pin_e fuelPumpPin; // offset 560 pin_output_mode_e fuelPumpPinMode; // Throttle pedal, secondary channel. // offset 561 adc_channel_e throttlePedalPositionSecondAdcChannel; // Check engine light, also malfunction indicator light. Always blinks once on boot. // offset 562 output_pin_e malfunctionIndicatorPin; // offset 564 pin_output_mode_e malfunctionIndicatorPinMode; // offset 565 pin_output_mode_e fanPinMode; // offset 566 output_pin_e fanPin; // Some cars have a switch to indicate that clutch pedal is all the way down // offset 568 switch_input_pin_e clutchDownPin; // offset 570 output_pin_e alternatorControlPin; // offset 572 pin_output_mode_e alternatorControlPinMode; // offset 573 pin_input_mode_e clutchDownPinMode; // offset 574 pin_output_mode_e electronicThrottlePin1Mode; // offset 575 spi_device_e max31855spiDevice; // offset 576 Gpio debugTriggerSync; // offset 578 Gpio mc33972_cs; // offset 580 pin_output_mode_e mc33972_csPinMode; // Useful in Research&Development phase // offset 581 adc_channel_e auxFastSensor1_adcChannel; // First throttle body, second sensor. // offset 582 adc_channel_e tps1_2AdcChannel; // Second throttle body, second sensor. // offset 583 adc_channel_e tps2_2AdcChannel; // % // offset 584 uint8_t fuelLevelValues[FUEL_LEVEL_TABLE_COUNT]; // 0.1 is a good default value // x // offset 592 float idle_antiwindupFreq; // offset 596 brain_input_pin_e triggerInputPins[TRIGGER_INPUT_PIN_COUNT]; // Minimum allowed time for the boost phase. If the boost target current is reached before this time elapses, it is assumed that the injector has failed short circuit. // us // offset 600 uint16_t mc33_t_min_boost; // offset 602 output_pin_e tachOutputPin; // offset 604 pin_output_mode_e tachOutputPinMode; // offset 605 adc_channel_e maf2AdcChannel; // offset 606 output_pin_e mainRelayPin; // offset 608 Gpio sdCardCsPin; // set_can_tx_pin X // offset 610 Gpio canTxPin; // set_can_rx_pin X // offset 612 Gpio canRxPin; // offset 614 pin_input_mode_e throttlePedalUpPinMode; // Additional idle % while A/C is active // % // offset 615 uint8_t acIdleExtraOffset; // Ratio between the wheels and your transmission output. // ratio // offset 616 scaled_channel finalGearRatio; // offset 618 brain_input_pin_e tcuInputSpeedSensorPin; // offset 620 uint8_t tcuInputSpeedSensorTeeth; // offset 621 pin_output_mode_e mainRelayPinMode; // Voltage when the wastegate is closed. // You probably don't have one of these! // mv // offset 622 uint16_t wastegatePositionMin; // Voltage when the wastegate is fully open. // You probably don't have one of these! // 1 volt = 1000 units // mv // offset 624 uint16_t wastegatePositionMax; // Some Subaru and some Mazda use double-solenoid idle air valve // offset 626 output_pin_e secondSolenoidPin; // Secondary TTL channel baud rate // BPs // offset 628 uint32_t tunerStudioSerialSpeed; // Just for reference really, not taken into account by any logic at this point // CR // offset 632 float compressionRatio; // Generate a synthetic trigger signal for an external ECU // offset 636 Gpio triggerSimulatorPins[TRIGGER_SIMULATOR_PIN_COUNT]; // g/s // offset 640 scaled_channel fordInjectorSmallPulseSlope; // offset 642 uint8_t unused638[2]; // offset 644 bit 0 bool is_enabled_spi_1 : 1 {}; // offset 644 bit 1 bool is_enabled_spi_2 : 1 {}; // offset 644 bit 2 bool is_enabled_spi_3 : 1 {}; // enable sd/disable sd // offset 644 bit 3 bool isSdCardEnabled : 1 {}; // Use 11 bit (standard) or 29 bit (extended) IDs for rusEFI verbose CAN format. // offset 644 bit 4 bool rusefiVerbose29b : 1 {}; // offset 644 bit 5 bool isVerboseAlternator : 1 {}; // This setting should only be used if you have a stepper motor idle valve and a stepper motor driver installed. // offset 644 bit 6 bool useStepperIdle : 1 {}; // offset 644 bit 7 bool enabledStep1Limiter : 1 {}; // offset 644 bit 8 bool verboseTLE8888 : 1 {}; // CAN broadcast using custom rusEFI protocol // enable can_broadcast/disable can_broadcast // offset 644 bit 9 bool enableVerboseCanTx : 1 {}; // offset 644 bit 10 bool etb1configured : 1 {}; // offset 644 bit 11 bool etb2configured : 1 {}; // Useful for individual intakes // offset 644 bit 12 bool measureMapOnlyInOneCylinder : 1 {}; // offset 644 bit 13 bool stepperForceParkingEveryRestart : 1 {}; // If enabled, try to fire the engine before a full engine cycle has been completed using RPM estimated from the last 90 degrees of engine rotation. As soon as the trigger syncs plus 90 degrees rotation, fuel and ignition events will occur. If disabled, worst case may require up to 4 full crank rotations before any events are scheduled. // offset 644 bit 14 bool isFasterEngineSpinUpEnabled : 1 {}; // This setting disables fuel injection while the engine is in overrun, this is useful as a fuel saving measure and to prevent back firing. // offset 644 bit 15 bool coastingFuelCutEnabled : 1 {}; // Override the IAC position during overrun conditions to help reduce engine breaking, this can be helpful for large engines in light weight cars or engines that have trouble returning to idle. // offset 644 bit 16 bool useIacTableForCoasting : 1 {}; // offset 644 bit 17 bool useIdleTimingPidControl : 1 {}; // Allows disabling the ETB when the engine is stopped. You may not like the power draw or PWM noise from the motor, so this lets you turn it off until it's necessary. // offset 644 bit 18 bool disableEtbWhenEngineStopped : 1 {}; // offset 644 bit 19 bool is_enabled_spi_4 : 1 {}; // Disable the electronic throttle motor and DC idle motor for testing. // This mode is for testing ETB/DC idle position sensors, etc without actually driving the throttle. // offset 644 bit 20 bool pauseEtbControl : 1 {}; // offset 644 bit 21 bool alignEngineSnifferAtTDC : 1 {}; // AEM X-Series or rusEFI Wideband // offset 644 bit 22 bool enableAemXSeries : 1 {}; // offset 644 bit 23 bool unusedBit_195_23 : 1 {}; // offset 644 bit 24 bool unusedBit_195_24 : 1 {}; // offset 644 bit 25 bool unusedBit_195_25 : 1 {}; // offset 644 bit 26 bool unusedBit_195_26 : 1 {}; // offset 644 bit 27 bool unusedBit_195_27 : 1 {}; // offset 644 bit 28 bool unusedBit_195_28 : 1 {}; // offset 644 bit 29 bool unusedBit_195_29 : 1 {}; // offset 644 bit 30 bool unusedBit_195_30 : 1 {}; // offset 644 bit 31 bool unusedBit_195_31 : 1 {}; // offset 648 brain_input_pin_e logicAnalyzerPins[LOGIC_ANALYZER_CHANNEL_COUNT]; // offset 656 uint32_t verboseCanBaseAddress; // Boost Voltage // v // offset 660 uint8_t mc33_hvolt; // Minimum MAP before closed loop boost is enabled. Use to prevent misbehavior upon entering boost. // kPa // offset 661 uint8_t minimumBoostClosedLoopMap; // Optional Radiator Fan used with A/C // offset 662 output_pin_e acFanPin; // offset 664 pin_output_mode_e acFanPinMode; // offset 665 spi_device_e l9779spiDevice; // volts // offset 666 scaled_channel dwellVoltageCorrVoltBins[DWELL_CURVE_SIZE]; // multiplier // offset 674 scaled_channel dwellVoltageCorrValues[DWELL_CURVE_SIZE]; // kg // offset 682 uint16_t vehicleWeight; // How far above idle speed do we consider idling? // For example, if target = 800, this param = 200, then anything below 1000 RPM is considered idle. // RPM // offset 684 int16_t idlePidRpmUpperLimit; // Apply nonlinearity correction below a pulse of this duration. Pulses longer than this duration will receive no adjustment. // ms // offset 686 scaled_channel applyNonlinearBelowPulse; // offset 688 Gpio lps25BaroSensorScl; // offset 690 Gpio lps25BaroSensorSda; // offset 692 brain_input_pin_e vehicleSpeedSensorInputPin; // Some vehicles have a switch to indicate that clutch pedal is all the way up // offset 694 switch_input_pin_e clutchUpPin; // offset 696 InjectorNonlinearMode injectorNonlinearMode; // offset 697 pin_input_mode_e clutchUpPinMode; // offset 698 Gpio max31855_cs[EGT_CHANNEL_COUNT]; // Continental/GM flex fuel sensor, 50-150hz type // offset 714 brain_input_pin_e flexSensorPin; // offset 716 Gpio test557pin; // offset 718 pin_output_mode_e stepperDirectionPinMode; // offset 719 spi_device_e mc33972spiDevice; // Stoichiometric ratio for your secondary fuel. This value is used when the Flex Fuel sensor indicates E100, typically 9.0 // :1 // offset 720 scaled_channel stoichRatioSecondary; // Maximum allowed ETB position. Some throttles go past fully open, so this allows you to limit it to fully open. // % // offset 721 uint8_t etbMaximumPosition; // Rate the ECU will log to the SD card, in hz (log lines per second). // hz // offset 722 uint16_t sdCardLogFrequency; // offset 724 Gpio debugMapAveraging; // offset 726 output_pin_e starterRelayDisablePin; // On some vehicles we can disable starter once engine is already running // offset 728 pin_output_mode_e starterRelayDisablePinMode; // offset 729 imu_type_e imuType; // offset 730 switch_input_pin_e startStopButtonPin; // This many MAP samples are used to estimate the current MAP. This many samples are considered, and the minimum taken. Recommended value is 1 for single-throttle engines, and your number of cylinders for individual throttle bodies. // count // offset 732 int mapMinBufferLength; // Below this throttle position, the engine is considered idling. If you have an electronic throttle, this checks accelerator pedal position instead of throttle position, and should be set to 1-2%. // % // offset 736 int16_t idlePidDeactivationTpsThreshold; // % // offset 738 int16_t stepperParkingExtraSteps; // ADC // offset 740 uint16_t tps1SecondaryMin; // ADC // offset 742 uint16_t tps1SecondaryMax; // rpm // offset 744 int16_t antiLagRpmTreshold; // Maximum time to crank starter when start/stop button is pressed // Seconds // offset 746 uint16_t startCrankingDuration; // offset 748 uint8_t unused748[3]; // offset 751 pin_output_mode_e acRelayPinMode; // offset 752 output_pin_e acRelayPin; // offset 754 maf_sensor_type_e mafSensorType; // offset 755 spi_device_e drv8860spiDevice; // offset 756 script_setting_t scriptSetting[SCRIPT_SETTING_COUNT]; // offset 788 Gpio spi1mosiPin; // offset 790 Gpio spi1misoPin; // offset 792 Gpio spi1sckPin; // offset 794 Gpio spi2mosiPin; // offset 796 Gpio spi2misoPin; // offset 798 Gpio spi2sckPin; // offset 800 Gpio spi3mosiPin; // offset 802 Gpio spi3misoPin; // offset 804 Gpio spi3sckPin; // offset 806 uart_device_e consoleUartDevice; // rusEFI console Sensor Sniffer mode // offset 807 sensor_chart_e sensorChartMode; // offset 808 bit 0 bool clutchUpPinInverted : 1 {}; // offset 808 bit 1 bool clutchDownPinInverted : 1 {}; // If enabled we use two H-bridges to drive stepper idle air valve // offset 808 bit 2 bool useHbridgesToDriveIdleStepper : 1 {}; // offset 808 bit 3 bool multisparkEnable : 1 {}; // offset 808 bit 4 bool enableLaunchRetard : 1 {}; // Read VSS from OEM CAN bus according to selected CAN vehicle configuration. // offset 808 bit 5 bool enableCanVss : 1 {}; // offset 808 bit 6 bool enableInnovateLC2 : 1 {}; // offset 808 bit 7 bool showHumanReadableWarning : 1 {}; // If enabled, adjust at a constant rate instead of a rate proportional to the current lambda error. This mode may be easier to tune, and more tolerant of sensor noise. // offset 808 bit 8 bool stftIgnoreErrorMagnitude : 1 {}; // offset 808 bit 9 bool enableSoftwareKnock : 1 {}; // Verbose info in console below engineSnifferRpmThreshold // enable vvt_details // offset 808 bit 10 bool verboseVVTDecoding : 1 {}; // get invertCamVVTSignal // offset 808 bit 11 bool invertCamVVTSignal : 1 {}; // offset 808 bit 12 bool unused804b12 : 1 {}; // offset 808 bit 13 bool knockBankCyl1 : 1 {}; // offset 808 bit 14 bool knockBankCyl2 : 1 {}; // offset 808 bit 15 bool knockBankCyl3 : 1 {}; // offset 808 bit 16 bool knockBankCyl4 : 1 {}; // offset 808 bit 17 bool knockBankCyl5 : 1 {}; // offset 808 bit 18 bool knockBankCyl6 : 1 {}; // offset 808 bit 19 bool knockBankCyl7 : 1 {}; // offset 808 bit 20 bool knockBankCyl8 : 1 {}; // offset 808 bit 21 bool knockBankCyl9 : 1 {}; // offset 808 bit 22 bool knockBankCyl10 : 1 {}; // offset 808 bit 23 bool knockBankCyl11 : 1 {}; // offset 808 bit 24 bool knockBankCyl12 : 1 {}; // offset 808 bit 25 bool tcuEnabled : 1 {}; // offset 808 bit 26 bool canBroadcastUseChannelTwo : 1 {}; // If enabled we use four Push-Pull outputs to directly drive stepper idle air valve coilss // offset 808 bit 27 bool useRawOutputToDriveIdleStepper : 1 {}; // Print incoming and outgoing second bus CAN messages in rusEFI console // offset 808 bit 28 bool verboseCan2 : 1 {}; // offset 808 bit 29 bool unusedBit_288_29 : 1 {}; // offset 808 bit 30 bool unusedBit_288_30 : 1 {}; // offset 808 bit 31 bool unusedBit_288_31 : 1 {}; // offset 812 dc_io etbIo[ETB_COUNT]; // Wastegate control Solenoid // offset 828 output_pin_e boostControlPin; // offset 830 pin_output_mode_e boostControlPinMode; // offset 831 boostType_e boostType; // offset 832 switch_input_pin_e ALSActivatePin; // offset 834 switch_input_pin_e launchActivatePin; // offset 836 pid_s boostPid; // Hz // offset 856 int boostPwmFrequency; // offset 860 launchActivationMode_e launchActivationMode; // offset 861 antiLagActivationMode_e antiLagActivationMode; // offset 862 Gpio mc33816_flag0; // Disabled above this speed // Kph // offset 864 int launchSpeedThreshold; // Range from Launch RPM for Timing Retard to activate // RPM // offset 868 int launchTimingRpmRange; // Extra Fuel Added // % // offset 872 int launchFuelAdded; // Duty Cycle for the Boost Solenoid // % // offset 876 int launchBoostDuty; // Range from Launch RPM to activate Hard Cut // RPM // offset 880 int hardCutRpmRange; // offset 884 float turbochargerFilter; // offset 888 int launchTpsThreshold; // offset 892 float launchActivateDelay; // offset 896 stft_s stft; // offset 920 dc_io stepperDcIo[DC_PER_STEPPER]; // For example, BMW, GM or Chevrolet // REQUIRED for rusEFI Online // offset 936 vehicle_info_t engineMake; // For example, LS1 or NB2 // REQUIRED for rusEFI Online // offset 968 vehicle_info_t engineCode; // For example, Hunchback or Orange Miata // Vehicle name has to be unique between your vehicles. // REQUIRED for rusEFI Online // offset 1000 vehicle_info_t vehicleName; // offset 1032 output_pin_e tcu_solenoid[TCU_SOLENOID_COUNT]; // offset 1044 dc_function_e etbFunctions[ETB_COUNT]; // offset 1046 Gpio drv8860_cs; // offset 1048 pin_output_mode_e drv8860_csPinMode; // offset 1049 idle_mode_e idleMode; // offset 1050 Gpio drv8860_miso; // volt // offset 1052 scaled_channel fuelLevelBins[FUEL_LEVEL_TABLE_COUNT]; // offset 1068 output_pin_e luaOutputPins[LUA_PWM_COUNT]; // Angle between cam sensor and VVT zero position // value // offset 1084 scaled_channel vvtOffsets[CAM_INPUTS_COUNT]; // offset 1092 vr_threshold_s vrThreshold[VR_THRESHOLD_COUNT]; // offset 1124 gppwm_note_t gpPwmNote[GPPWM_CHANNELS]; // ADC // offset 1188 uint16_t tps2SecondaryMin; // ADC // offset 1190 uint16_t tps2SecondaryMax; // Select which bus the wideband controller is attached to. // offset 1192 bit 0 bool widebandOnSecondBus : 1 {}; // Enables lambda sensor closed loop feedback for fuelling. // offset 1192 bit 1 bool fuelClosedLoopCorrectionEnabled : 1 {}; // Print details into rusEFI console // enable verbose_idle // offset 1192 bit 2 bool isVerboseIAC : 1 {}; // offset 1192 bit 3 bool boardUseTachPullUp : 1 {}; // offset 1192 bit 4 bool boardUseTempPullUp : 1 {}; // offset 1192 bit 5 bool yesUnderstandLocking : 1 {}; // Sometimes we have a performance issue while printing error // offset 1192 bit 6 bool silentTriggerError : 1 {}; // offset 1192 bit 7 bool useLinearCltSensor : 1 {}; // enable can_read/disable can_read // offset 1192 bit 8 bool canReadEnabled : 1 {}; // enable can_write/disable can_write // offset 1192 bit 9 bool canWriteEnabled : 1 {}; // offset 1192 bit 10 bool useLinearIatSensor : 1 {}; // offset 1192 bit 11 bool boardUse2stepPullDown : 1 {}; // Treat milliseconds value as duty cycle value, i.e. 0.5ms would become 50% // offset 1192 bit 12 bool tachPulseDurationAsDutyCycle : 1 {}; // This enables smart alternator control and activates the extra alternator settings. // offset 1192 bit 13 bool isAlternatorControlEnabled : 1 {}; // https://wiki.rusefi.com/Trigger-Configuration-Guide // This setting flips the signal from the primary engine speed sensor. // offset 1192 bit 14 bool invertPrimaryTriggerSignal : 1 {}; // https://wiki.rusefi.com/Trigger-Configuration-Guide // This setting flips the signal from the secondary engine speed sensor. // offset 1192 bit 15 bool invertSecondaryTriggerSignal : 1 {}; // offset 1192 bit 16 bool cutFuelOnHardLimit : 1 {}; // Be careful enabling this: some engines are known to self-disassemble their valvetrain with a spark cut. Fuel cut is much safer. // offset 1192 bit 17 bool cutSparkOnHardLimit : 1 {}; // offset 1192 bit 18 bool launchFuelCutEnable : 1 {}; // This is the Cut Mode normally used // offset 1192 bit 19 bool launchSparkCutEnable : 1 {}; // offset 1192 bit 20 bool boardUseCrankPullUp : 1 {}; // offset 1192 bit 21 bool boardUseCamPullDown : 1 {}; // offset 1192 bit 22 bool boardUseCamVrPullUp : 1 {}; // offset 1192 bit 23 bool boardUseD2PullDown : 1 {}; // offset 1192 bit 24 bool boardUseD3PullDown : 1 {}; // offset 1192 bit 25 bool boardUseD4PullDown : 1 {}; // offset 1192 bit 26 bool boardUseD5PullDown : 1 {}; // offset 1192 bit 27 bool verboseIsoTp : 1 {}; // offset 1192 bit 28 bool engineSnifferFocusOnInputs : 1 {}; // offset 1192 bit 29 bool launchActivateInverted : 1 {}; // offset 1192 bit 30 bool twoStroke : 1 {}; // Where is your primary skipped wheel located? // offset 1192 bit 31 bool skippedWheelOnCam : 1 {}; // A/C button input // offset 1196 switch_input_pin_e acSwitch; // offset 1198 adc_channel_e vRefAdcChannel; // Expected neutral position // % // offset 1199 uint8_t etbNeutralPosition; // offset 1200 bit 0 bool isInjectionEnabled : 1 {}; // offset 1200 bit 1 bool isIgnitionEnabled : 1 {}; // When enabled if TPS is held above 95% no fuel is injected while cranking to clear excess fuel from the cylinders. // offset 1200 bit 2 bool isCylinderCleanupEnabled : 1 {}; // Should we use tables to vary tau/beta based on CLT/MAP, or just with fixed values? // offset 1200 bit 3 bool complexWallModel : 1 {}; // offset 1200 bit 4 bool alwaysInstantRpm : 1 {}; // offset 1200 bit 5 bool isMapAveragingEnabled : 1 {}; // If enabled, use separate temperature multiplier table for cranking idle position. // If disabled, use normal running multiplier table applied to the cranking base position. // offset 1200 bit 6 bool overrideCrankingIacSetting : 1 {}; // This activates a separate ignition timing table for idle conditions, this can help idle stability by using ignition retard and advance either side of the desired idle speed. Extra retard at low idle speeds will prevent stalling and extra advance at high idle speeds can help reduce engine power and slow the idle speed. // offset 1200 bit 7 bool useSeparateAdvanceForIdle : 1 {}; // offset 1200 bit 8 bool isWaveAnalyzerEnabled : 1 {}; // This activates a separate fuel table for Idle, this allows fine tuning of the idle fuelling. // offset 1200 bit 9 bool useSeparateVeForIdle : 1 {}; // Verbose info in console below engineSnifferRpmThreshold // enable trigger_details // offset 1200 bit 10 bool verboseTriggerSynchDetails : 1 {}; // Usually if we have no trigger events that means engine is stopped // Unless we are troubleshooting and spinning the engine by hand - this case a longer // delay is needed // offset 1200 bit 11 bool isManualSpinningMode : 1 {}; // This is needed if your coils are individually wired and you wish to use batch injection. // enable two_wire_batch_injection // offset 1200 bit 12 bool twoWireBatchInjection : 1 {}; // offset 1200 bit 13 bool neverInstantRpm : 1 {}; // offset 1200 bit 14 bool unused1200b14 : 1 {}; // offset 1200 bit 15 bool useFixedBaroCorrFromMap : 1 {}; // In Constant mode, timing is automatically tapered to running as RPM increases. // In Table mode, the "Cranking ignition advance" table is used directly. // offset 1200 bit 16 bool useSeparateAdvanceForCranking : 1 {}; // This enables the various ignition corrections during cranking (IAT, CLT, FSIO and PID idle). // You probably don't need this. // offset 1200 bit 17 bool useAdvanceCorrectionsForCranking : 1 {}; // Enable a second cranking table to use for E100 flex fuel, interpolating between the two based on flex fuel sensor. // offset 1200 bit 18 bool flexCranking : 1 {}; // This flag allows to use a special 'PID Multiplier' table (0.0-1.0) to compensate for nonlinear nature of IAC-RPM controller // offset 1200 bit 19 bool useIacPidMultTable : 1 {}; // offset 1200 bit 20 bool isBoostControlEnabled : 1 {}; // Interpolates the Ignition Retard from 0 to 100% within the RPM Range // offset 1200 bit 21 bool launchSmoothRetard : 1 {}; // Some engines are OK running semi-random sequential while other engine require phase synchronization // offset 1200 bit 22 bool isPhaseSyncRequiredForIgnition : 1 {}; // If enabled, use a curve for RPM limit (based on coolant temperature) instead of a constant value. // offset 1200 bit 23 bool useCltBasedRpmLimit : 1 {}; // If enabled, don't wait for engine start to heat O2 sensors. WARNING: this will reduce the life of your sensor, as condensation in the exhaust from a cold start can crack the sensing element. // offset 1200 bit 24 bool forceO2Heating : 1 {}; // If increased VVT duty cycle increases the indicated VVT angle, set this to 'advance'. If it decreases, set this to 'retard'. Most intake cams use 'advance', and most exhaust cams use 'retard'. // offset 1200 bit 25 bool invertVvtControlIntake : 1 {}; // If increased VVT duty cycle increases the indicated VVT angle, set this to 'advance'. If it decreases, set this to 'retard'. Most intake cams use 'advance', and most exhaust cams use 'retard'. // offset 1200 bit 26 bool invertVvtControlExhaust : 1 {}; // offset 1200 bit 27 bool useBiQuadOnAuxSpeedSensors : 1 {}; // 'Trigger' mode will write a high speed log of trigger events (warning: uses lots of space!). 'Normal' mode will write a standard MLG of sensors, engine function, etc. similar to the one captured in TunerStudio. // offset 1200 bit 28 bool sdTriggerLog : 1 {}; // offset 1200 bit 29 bool ALSActivateInverted : 1 {}; // offset 1200 bit 30 bool unusedBit_393_30 : 1 {}; // offset 1200 bit 31 bool unusedBit_393_31 : 1 {}; // count // offset 1204 uint32_t engineChartSize; // mult // offset 1208 float turboSpeedSensorMultiplier; // offset 1212 Gpio camInputsDebug[CAM_INPUTS_COUNT]; // Extra idle target speed when A/C is enabled. Some cars need the extra speed to keep the AC efficient while idling. // RPM // offset 1220 int16_t acIdleRpmBump; // seconds // offset 1222 int16_t warningPeriod; // angle // offset 1224 float knockDetectionWindowStart; // angle // offset 1228 float knockDetectionWindowEnd; // ms // offset 1232 float idleStepperReactionTime; // count // offset 1236 int idleStepperTotalSteps; // TODO: finish this #413 // sec // offset 1240 float noAccelAfterHardLimitPeriodSecs; // At what trigger index should some MAP-related math be executed? This is a performance trick to reduce load on synchronization trigger callback. // index // offset 1244 int mapAveragingSchedulingAtIndex; // Duration in ms or duty cycle depending on selected mode // offset 1248 float tachPulseDuractionMs; // Length of time the deposited wall fuel takes to dissipate after the start of acceleration. // Seconds // offset 1252 float wwaeTau; // offset 1256 pid_s alternatorControl; // offset 1276 pid_s etb; // offset 1296 Gpio triggerInputDebugPins[TRIGGER_INPUT_PIN_COUNT]; // RPM range above upper limit for extra air taper,"RPM", 1, 0, 0, 1500, 0 // offset 1300 int16_t airTaperRpmRange; // offset 1302 brain_input_pin_e turboSpeedSensorInputPin; // ADC // offset 1304 int16_t tps2Min; // ADC // offset 1306 int16_t tps2Max; // offset 1308 output_pin_e starterControlPin; // offset 1310 pin_input_mode_e startStopButtonMode; // Pulse // offset 1311 uint8_t tachPulsePerRev; // kPa value which is too low to be true // kPa // offset 1312 float mapErrorDetectionTooLow; // kPa value which is too high to be true // kPa // offset 1316 float mapErrorDetectionTooHigh; // How long to wait for the spark to fire before recharging the coil for another spark. // ms // offset 1320 scaled_channel multisparkSparkDuration; // This sets the dwell time for subsequent sparks. The main spark's dwell is set by the dwell table. // ms // offset 1322 scaled_channel multisparkDwell; // offset 1324 pid_s idleRpmPid; // 0 = No fuel settling on port walls 1 = All the fuel settling on port walls setting this to 0 disables the wall wetting enrichment. // Fraction // offset 1344 float wwaeBeta; // offset 1348 Gpio auxValves[AUX_DIGITAL_VALVE_COUNT]; // offset 1352 switch_input_pin_e tcuUpshiftButtonPin; // offset 1354 switch_input_pin_e tcuDownshiftButtonPin; // voltage // offset 1356 float throttlePedalUpVoltage; // Pedal in the floor // voltage // offset 1360 float throttlePedalWOTVoltage; // on IGN voltage detection turn fuel pump on to build fuel pressure // seconds // offset 1364 int16_t startUpFuelPumpDuration; // If the RPM closer to target than this value, disable closed loop idle correction to prevent oscillation // RPM // offset 1366 int16_t idlePidRpmDeadZone; // This is the target battery voltage the alternator PID control will attempt to maintain // Volts // offset 1368 float targetVBatt; // Turns off alternator output above specified TPS, enabling this reduced parasitic drag on the engine at full load. // % // offset 1372 float alternatorOffAboveTps; // This is the duration in cycles that the IAC will take to reach its normal idle position, it can be used to hold the idle higher for a few seconds after cranking to improve startup. // cycles // offset 1376 int16_t afterCrankingIACtaperDuration; // Extra IAC, in percent between 0 and 100, tapered between zero and idle deactivation TPS value // percent // offset 1378 int16_t iacByTpsTaper; // Auxiliary sensor serial, not to be confused with secondary calibration serial // offset 1380 Gpio auxSerialTxPin; // Auxiliary sensor serial, not to be confused with secondary calibration serial // offset 1382 Gpio auxSerialRxPin; // offset 1384 Gpio LIS302DLCsPin; // How long to look back for TPS-based acceleration enrichment. Increasing this time will trigger enrichment for longer when a throttle position change occurs. // sec // offset 1386 scaled_channel tpsAccelLookback; // Below this speed, disable DFCO. Use this to prevent jerkiness from fuel enable/disable in low gears. // kph // offset 1387 uint8_t coastingFuelCutVssLow; // Above this speed, allow DFCO. Use this to prevent jerkiness from fuel enable/disable in low gears. // kph // offset 1388 uint8_t coastingFuelCutVssHigh; // Pause closed loop fueling after deceleration fuel cut occurs. Set this to a little longer than however long is required for normal fueling behavior to resume after fuel cut. // sec // offset 1389 scaled_channel noFuelTrimAfterDfcoTime; // need 4 byte alignment // units // offset 1390 uint8_t alignmentFill_at_1390[2]; // Maximum change delta of TPS percentage over the 'length'. Actual TPS change has to be above this value in order for TPS/TPS acceleration to kick in. // roc // offset 1392 float tpsAccelEnrichmentThreshold; // offset 1396 brain_input_pin_e auxSpeedSensorInputPin[2]; // offset 1400 uint8_t totalGearsCount; // Sets what part of injection's is controlled by the injection phase table. // offset 1401 InjectionTimingMode injectionTimingMode; // See http://rusefi.com/s/debugmode // offset 1402 debug_mode_e debugMode; // Additional idle % when fan #1 is active // % // offset 1403 uint8_t fan1ExtraIdle; // Band rate for primary TTL // BPs // offset 1404 uint32_t uartConsoleSerialSpeed; // For decel we simply multiply delta of TPS and tFor decel we do not use table?! // roc // offset 1408 float tpsDecelEnleanmentThreshold; // Magic multiplier, we multiply delta of TPS and get fuel squirt duration // coeff // offset 1412 float tpsDecelEnleanmentMultiplier; // BPs // offset 1416 uint32_t auxSerialSpeed; // voltage // offset 1420 float throttlePedalSecondaryUpVoltage; // Pedal in the floor // voltage // offset 1424 float throttlePedalSecondaryWOTVoltage; // set can_baudrate // offset 1428 can_baudrate_e canBaudRate; // Override the Y axis (load) value used for the VE table. // Advanced users only: If you aren't sure you need this, you probably don't need this. // offset 1429 ve_override_e veOverrideMode; // offset 1430 can_baudrate_e can2BaudRate; // Override the Y axis (load) value used for the AFR table. // Advanced users only: If you aren't sure you need this, you probably don't need this. // offset 1431 load_override_e afrOverrideMode; // A // offset 1432 scaled_channel mc33_hpfp_i_peak; // A // offset 1433 scaled_channel mc33_hpfp_i_hold; // How long to deactivate power when hold current is reached before applying power again // us // offset 1434 uint8_t mc33_hpfp_i_hold_off; // Maximum amount of time the solenoid can be active before assuming a programming error // ms // offset 1435 uint8_t mc33_hpfp_max_hold; // Enable if DC-motor driver (H-bridge) inverts the signals (eg. RZ7899 on Hellen boards) // offset 1436 bit 0 bool stepperDcInvertedPins : 1 {}; // Allow OpenBLT on Primary CAN // offset 1436 bit 1 bool canOpenBLT : 1 {}; // Allow OpenBLT on Secondary CAN // offset 1436 bit 2 bool can2OpenBLT : 1 {}; // Select whether to configure injector flow in volumetric flow (defualt, cc/min) or mass flow (g/s). // offset 1436 bit 3 bool injectorFlowAsMassFlow : 1 {}; // offset 1436 bit 4 bool unusedBit_467_4 : 1 {}; // offset 1436 bit 5 bool unusedBit_467_5 : 1 {}; // offset 1436 bit 6 bool unusedBit_467_6 : 1 {}; // offset 1436 bit 7 bool unusedBit_467_7 : 1 {}; // offset 1436 bit 8 bool unusedBit_467_8 : 1 {}; // offset 1436 bit 9 bool unusedBit_467_9 : 1 {}; // offset 1436 bit 10 bool unusedBit_467_10 : 1 {}; // offset 1436 bit 11 bool unusedBit_467_11 : 1 {}; // offset 1436 bit 12 bool unusedBit_467_12 : 1 {}; // offset 1436 bit 13 bool unusedBit_467_13 : 1 {}; // offset 1436 bit 14 bool unusedBit_467_14 : 1 {}; // offset 1436 bit 15 bool unusedBit_467_15 : 1 {}; // offset 1436 bit 16 bool unusedBit_467_16 : 1 {}; // offset 1436 bit 17 bool unusedBit_467_17 : 1 {}; // offset 1436 bit 18 bool unusedBit_467_18 : 1 {}; // offset 1436 bit 19 bool unusedBit_467_19 : 1 {}; // offset 1436 bit 20 bool unusedBit_467_20 : 1 {}; // offset 1436 bit 21 bool unusedBit_467_21 : 1 {}; // offset 1436 bit 22 bool unusedBit_467_22 : 1 {}; // offset 1436 bit 23 bool unusedBit_467_23 : 1 {}; // offset 1436 bit 24 bool unusedBit_467_24 : 1 {}; // offset 1436 bit 25 bool unusedBit_467_25 : 1 {}; // offset 1436 bit 26 bool unusedBit_467_26 : 1 {}; // offset 1436 bit 27 bool unusedBit_467_27 : 1 {}; // offset 1436 bit 28 bool unusedBit_467_28 : 1 {}; // offset 1436 bit 29 bool unusedBit_467_29 : 1 {}; // offset 1436 bit 30 bool unusedBit_467_30 : 1 {}; // offset 1436 bit 31 bool unusedBit_467_31 : 1 {}; // Time between bench test pulses // ms // offset 1440 scaled_channel benchTestOffTime; // offset 1441 uint8_t unused1445[2]; // offset 1443 pin_input_mode_e launchActivatePinMode; // set_can2_tx_pin X // offset 1444 Gpio can2TxPin; // set_can2_rx_pin X // offset 1446 Gpio can2RxPin; // offset 1448 pin_output_mode_e starterControlPinMode; // offset 1449 adc_channel_e wastegatePositionSensor; // Override the Y axis (load) value used for the ignition table. // Advanced users only: If you aren't sure you need this, you probably don't need this. // offset 1450 load_override_e ignOverrideMode; // Select which fuel pressure sensor measures the pressure of the fuel at your injectors. // offset 1451 injector_pressure_type_e injectorPressureType; // offset 1452 output_pin_e hpfpValvePin; // offset 1454 pin_output_mode_e hpfpValvePinMode; // offset 1455 spi_device_e accelerometerSpiDevice; // MAP value above which fuel is cut in case of overboost. // Set to 0 to disable overboost cut. // kPa (absolute) // offset 1456 float boostCutPressure; // kg/h // offset 1460 scaled_channel tchargeBins[16]; // ratio // offset 1476 scaled_channel tchargeValues[16]; // Fixed timing, useful for TDC testing // deg // offset 1492 float fixedTiming; // MAP voltage for low point // v // offset 1496 float mapLowValueVoltage; // MAP voltage for low point // v // offset 1500 float mapHighValueVoltage; // EGO value correction // value // offset 1504 float egoValueShift; // VVT output // TODO: rename to vvtOutputs // offset 1508 output_pin_e vvtPins[CAM_INPUTS_COUNT]; // This is the IAC position during cranking, some engines start better if given more air during cranking to improve cylinder filling. // percent // offset 1516 int crankingIACposition; // offset 1520 float tChargeMinRpmMinTps; // offset 1524 float tChargeMinRpmMaxTps; // offset 1528 float tChargeMaxRpmMinTps; // offset 1532 float tChargeMaxRpmMaxTps; // offset 1536 pwm_freq_t vvtOutputFrequency[CAMS_PER_BANK]; // Hz // offset 1540 int alternatorPwmFrequency; // offset 1544 vvt_mode_e vvtMode[CAMS_PER_BANK]; // Additional idle % when fan #2 is active // % // offset 1546 uint8_t fan2ExtraIdle; // Delay to allow fuel pressure to build before firing the priming pulse. // sec // offset 1547 scaled_channel primingDelay; // offset 1548 adc_channel_e auxAnalogInputs[LUA_ANALOG_INPUT_COUNT]; // offset 1556 output_pin_e trailingCoilPins[MAX_CYLINDER_COUNT]; // offset 1580 tle8888_mode_e tle8888mode; // offset 1581 pin_output_mode_e LIS302DLCsPinMode; // None = I have a MAP-referenced fuel pressure regulator // Fixed rail pressure = I have an atmosphere-referenced fuel pressure regulator (returnless, typically) // Sensed rail pressure = I have a fuel pressure sensor // offset 1582 injector_compensation_mode_e injectorCompensationMode; // offset 1583 pin_output_mode_e fan2PinMode; // This is the pressure at which your injector flow is known. // For example if your injectors flow 400cc/min at 3.5 bar, enter 350kpa here. // kPa // offset 1584 float fuelReferencePressure; // Fuel multiplier (enrichment) immediately after engine start // mult // offset 1588 float postCrankingFactor; // Time over which to taper out after start enrichment // seconds // offset 1592 float postCrankingDurationSec; // offset 1596 ThermistorConf auxTempSensor1; // offset 1628 ThermistorConf auxTempSensor2; // Deg // offset 1660 int16_t knockSamplingDuration; // Hz // offset 1662 int16_t etbFreq; // offset 1664 pid_s etbWastegatePid; // For micro-stepping, make sure that PWM frequency (etbFreq) is high enough // offset 1684 stepper_num_micro_steps_e stepperNumMicroSteps; // Use to limit the current when the stepper motor is idle, not moving (100% = no limit) // % // offset 1685 uint8_t stepperMinDutyCycle; // Use to limit the max.current through the stepper motor (100% = no limit) // % // offset 1686 uint8_t stepperMaxDutyCycle; // offset 1687 spi_device_e sdCardSpiDevice; // per-cylinder timing correction // deg // offset 1688 angle_t timing_offset_cylinder[MAX_CYLINDER_COUNT]; // seconds // offset 1736 float idlePidActivationTime; // offset 1740 pin_mode_e spi1SckMode; // Modes count be used for 3v<>5v integration using pull-ups/pull-downs etc. // offset 1741 pin_mode_e spi1MosiMode; // offset 1742 pin_mode_e spi1MisoMode; // offset 1743 pin_mode_e spi2SckMode; // offset 1744 pin_mode_e spi2MosiMode; // offset 1745 pin_mode_e spi2MisoMode; // offset 1746 pin_mode_e spi3SckMode; // offset 1747 pin_mode_e spi3MosiMode; // offset 1748 pin_mode_e spi3MisoMode; // offset 1749 pin_output_mode_e stepperEnablePinMode; // ResetB // offset 1750 Gpio mc33816_rstb; // offset 1752 Gpio mc33816_driven; // Brake pedal switch // offset 1754 switch_input_pin_e brakePedalPin; // offset 1756 pin_input_mode_e brakePedalPinMode; // offset 1757 tChargeMode_e tChargeMode; // offset 1758 pin_input_mode_e tcuUpshiftButtonPinMode; // offset 1759 pin_input_mode_e tcuDownshiftButtonPinMode; // VVT output PID // TODO: rename to vvtPid // offset 1760 pid_s auxPid[CAMS_PER_BANK]; // offset 1800 float injectorCorrectionPolynomial[8]; // C // offset 1832 int8_t primeBins[8]; // offset 1840 linear_sensor_s oilPressure; // offset 1860 output_pin_e fan2Pin; // Cooling fan turn-on temperature threshold, in Celsius // deg C // offset 1862 uint8_t fan2OnTemperature; // Cooling fan turn-off temperature threshold, in Celsius // deg C // offset 1863 uint8_t fan2OffTemperature; // offset 1864 Gpio stepperEnablePin; // offset 1866 Gpio tle8888_cs; // offset 1868 pin_output_mode_e tle8888_csPinMode; // offset 1869 can_vss_nbc_e canVssNbcType; // offset 1870 Gpio mc33816_cs; // offset 1872 float auxFrequencyFilter; // RPM // offset 1876 int16_t vvtControlMinRpm; // offset 1878 brain_input_pin_e sentInputPins[SENT_INPUT_COUNT]; // offset 1880 int8_t launchFuelAdderPercent; // Time required to detect a stuck throttle. // sec // offset 1881 scaled_channel etbJamTimeout; // By the way ETB PID runs at 500hz, length in 1/500 of second here. // offset 1882 uint16_t etbExpAverageLength; // This sets the RPM above which fuel cut is active. // rpm // offset 1884 int16_t coastingFuelCutRpmHigh; // This sets the RPM below which fuel cut is deactivated, this prevents jerking or issues transitioning to idle // rpm // offset 1886 int16_t coastingFuelCutRpmLow; // Throttle position below which fuel cut is active. With an electronic throttle enabled, this checks against pedal position. // % // offset 1888 int16_t coastingFuelCutTps; // Fuel cutoff is disabled when the engine is cold. // C // offset 1890 int16_t coastingFuelCutClt; // Increases PID reaction for RPM stoichRatioPrimary; // iTerm max value // offset 2294 int16_t idlerpmpid_iTermMax; // This sets the range of the idle control on the ETB. At 100% idle position, the value specified here sets the base ETB position. // % // offset 2296 float etbIdleThrottleRange; // Select which fuel correction bank this cylinder belongs to. Group cylinders that share the same O2 sensor // offset 2300 uint8_t cylinderBankSelect[MAX_CYLINDER_COUNT]; // mg // offset 2312 scaled_channel primeValues[8]; // Trigger comparator center point voltage // V // offset 2320 scaled_channel triggerCompCenterVolt; // Trigger comparator hysteresis voltage (Min) // V // offset 2321 scaled_channel triggerCompHystMin; // Trigger comparator hysteresis voltage (Max) // V // offset 2322 scaled_channel triggerCompHystMax; // VR-sensor saturation RPM // RPM // offset 2323 scaled_channel triggerCompSensorSatRpm; // offset 2324 gppwm_channel gppwm[GPPWM_CHANNELS]; // Boost Current // mA // offset 2756 uint16_t mc33_i_boost; // Peak Current // mA // offset 2758 uint16_t mc33_i_peak; // Hold Current // mA // offset 2760 uint16_t mc33_i_hold; // Maximum allowed boost phase time. If the injector current doesn't reach the threshold before this time elapses, it is assumed that the injector is missing or has failed open circuit. // us // offset 2762 uint16_t mc33_t_max_boost; // us // offset 2764 uint16_t mc33_t_peak_off; // Peak phase duration // us // offset 2766 uint16_t mc33_t_peak_tot; // us // offset 2768 uint16_t mc33_t_bypass; // us // offset 2770 uint16_t mc33_t_hold_off; // Hold phase duration // us // offset 2772 uint16_t mc33_t_hold_tot; // offset 2774 pin_output_mode_e tcu_solenoid_mode[TCU_SOLENOID_COUNT]; // Knock sensor output knock detection threshold depending on current RPM. // dB // offset 2780 scaled_channel knockBaseNoise[ENGINE_NOISE_CURVE_SIZE]; // ratio // offset 2796 float triggerGapOverrideFrom[GAP_TRACKING_LENGTH]; // ratio // offset 2868 float triggerGapOverrideTo[GAP_TRACKING_LENGTH]; // Below this RPM, use camshaft information to synchronize the crank's position for full sequential operation. Use this if your cam sensor does weird things at high RPM. Set to 0 to disable, and always use cam to help sync crank. // rpm // offset 2940 scaled_channel maxCamPhaseResolveRpm; // Delay before cutting fuel. Set to 0 to cut immediately with no delay. May cause rumbles and pops out of your exhaust... // sec // offset 2941 scaled_channel dfcoDelay; // Delay before engaging the AC compressor. Set to 0 to engage immediately with no delay. Use this to prevent bogging at idle when AC engages. // sec // offset 2942 scaled_channel acDelay; // offset 2943 pin_input_mode_e acSwitchMode; // mg // offset 2944 scaled_channel fordInjectorSmallPulseBreakPoint; // multiplier // offset 2946 scaled_channel tpsTspCorrValues[TPS_TPS_ACCEL_CLT_CORR_TABLE]; // % // offset 2950 uint8_t etbJamIntegratorLimit; // lobes/cam // offset 2951 uint8_t hpfpCamLobes; // offset 2952 hpfp_cam_e hpfpCam; // Crank angle ATDC of first lobe peak // deg // offset 2953 uint8_t hpfpPeakPos; // If the requested activation time is below this angle, don't bother running the pump // deg // offset 2954 uint8_t hpfpMinAngle; // offset 2955 vin_number_t vinNumber; // Size of the pump chamber in cc. Typical Bosch HDP5 has a 9.0mm diameter, typical BMW N* stroke is 4.4mm. // cc // offset 2972 scaled_channel hpfpPumpVolume; // How long to keep the valve activated (in order to allow the pump to build pressure and keep the valve open on its own) // deg // offset 2974 uint8_t hpfpActivationAngle; // offset 2975 uint8_t issFilterReciprocal; // %/kPa // offset 2976 scaled_channel hpfpPidP; // %/kPa/lobe // offset 2978 scaled_channel hpfpPidI; // The fastest rate the target pressure can be reduced by. This is because HPFP have no way to bleed off pressure other than injecting fuel. // kPa/s // offset 2980 uint16_t hpfpTargetDecay; // % // offset 2982 scaled_channel hpfpLobeProfileQuantityBins[HPFP_LOBE_PROFILE_SIZE]; // deg // offset 2998 scaled_channel hpfpLobeProfileAngle[HPFP_LOBE_PROFILE_SIZE]; // volts // offset 3014 uint8_t hpfpDeadtimeVoltsBins[HPFP_DEADTIME_SIZE]; // ms // offset 3022 scaled_channel hpfpDeadtimeMS[HPFP_DEADTIME_SIZE]; // kPa // offset 3038 uint16_t hpfpTarget[HPFP_TARGET_SIZE][HPFP_TARGET_SIZE]; // load // offset 3238 scaled_channel hpfpTargetLoadBins[HPFP_TARGET_SIZE]; // RPM // offset 3258 scaled_channel hpfpTargetRpmBins[HPFP_TARGET_SIZE]; // % // offset 3268 int8_t hpfpCompensation[HPFP_COMPENSATION_SIZE][HPFP_COMPENSATION_SIZE]; // cc/lobe // offset 3368 scaled_channel hpfpCompensationLoadBins[HPFP_COMPENSATION_SIZE]; // RPM // offset 3388 scaled_channel hpfpCompensationRpmBins[HPFP_COMPENSATION_SIZE]; // offset 3398 output_pin_e stepper_raw_output[4]; // ratio // offset 3406 scaled_channel gearRatio[GEARS_COUNT]; // We need to give engine time to build oil pressure without diverting it to VVT // ms // offset 3422 uint16_t vvtActivationDelayMs; // deg C // offset 3424 int8_t wwCltBins[WWAE_TABLE_SIZE]; // offset 3432 scaled_channel wwTauCltValues[WWAE_TABLE_SIZE]; // offset 3440 scaled_channel wwBetaCltValues[WWAE_TABLE_SIZE]; // kPa // offset 3448 int8_t wwMapBins[WWAE_TABLE_SIZE]; // offset 3456 scaled_channel wwTauMapValues[WWAE_TABLE_SIZE]; // offset 3464 scaled_channel wwBetaMapValues[WWAE_TABLE_SIZE]; // offset 3472 GearControllerMode gearControllerMode; // offset 3473 TransmissionControllerMode transmissionControllerMode; // deg // offset 3474 uint16_t acrDisablePhase; // offset 3476 linear_sensor_s auxLinear1; // offset 3496 linear_sensor_s auxLinear2; // offset 3516 output_pin_e tcu_tcc_onoff_solenoid; // offset 3518 pin_output_mode_e tcu_tcc_onoff_solenoid_mode; // offset 3519 pin_output_mode_e tcu_tcc_pwm_solenoid_mode; // offset 3520 output_pin_e tcu_tcc_pwm_solenoid; // offset 3522 pwm_freq_t tcu_tcc_pwm_solenoid_freq; // offset 3524 output_pin_e tcu_pc_solenoid_pin; // offset 3526 pin_output_mode_e tcu_pc_solenoid_pin_mode; // offset 3527 pin_output_mode_e tcu_32_solenoid_pin_mode; // offset 3528 pwm_freq_t tcu_pc_solenoid_freq; // offset 3530 output_pin_e tcu_32_solenoid_pin; // offset 3532 pwm_freq_t tcu_32_solenoid_freq; // offset 3534 output_pin_e acrPin2; // % // offset 3536 float etbMinimumPosition; // offset 3540 uint16_t tuneHidingKey; // offset 3542 uint16_t highSpeedOffsets[HIGH_SPEED_COUNT]; // offset 3606 SentEtbType sentEtbType; // offset 3607 fuel_pressure_sensor_mode_e fuelPressureSensorMode; // offset 3608 Gpio luaDigitalInputPins[LUA_DIGITAL_INPUT_COUNT]; // RPM // offset 3624 scaled_channel tpsTspCorrValuesBins[TPS_TPS_ACCEL_CLT_CORR_TABLE]; // rpm // offset 3628 int16_t ALSMinRPM; // rpm // offset 3630 int16_t ALSMaxRPM; // sec // offset 3632 int16_t ALSMaxDuration; // C // offset 3634 int8_t ALSMinCLT; // C // offset 3635 int8_t ALSMaxCLT; // offset 3636 uint8_t alsMinTimeBetween; // offset 3637 uint8_t alsEtbPosition; // offset 3638 uint8_t acRelayAlternatorDutyAdder; // deg // offset 3639 uint8_t instantRpmRange; // % // offset 3640 int ALSIdleAdd; // % // offset 3644 int ALSEtbAdd; // offset 3648 int ALSSkipRatio; // % // offset 3652 uint8_t ALSMaxDriverThrottleIntent; // offset 3653 pin_input_mode_e ALSActivatePinMode; // For Ford TPS, use 53%. For Toyota ETCS-i, use ~65% // % // offset 3654 scaled_channel tpsSecondaryMaximum; // For Toyota ETCS-i, use ~69% // % // offset 3655 scaled_channel ppsSecondaryMaximum; // offset 3656 pin_input_mode_e luaDigitalInputPinModes[LUA_DIGITAL_INPUT_COUNT]; // If the hard limit is 7200rpm and hysteresis is 200rpm, then when the ECU sees 7200rpm, fuel/ign will cut, and stay cut until 7000rpm (7200-200) is reached // RPM // offset 3664 scaled_channel rpmHardLimitHyst; // units // offset 3665 uint8_t mainUnusedEnd[95]; }; static_assert(sizeof(engine_configuration_s) == 3760); struct cyl_trim_s { // offset 0 scaled_channel table[TRIM_SIZE][TRIM_SIZE]; }; static_assert(sizeof(cyl_trim_s) == 16); struct blend_table_s { // offset 0 scaled_channel table[8][8]; // Load // offset 128 uint16_t loadBins[8]; // RPM // offset 144 uint16_t rpmBins[8]; // offset 160 gppwm_channel_e blendParameter; // need 4 byte alignment // units // offset 161 uint8_t alignmentFill_at_161[1]; // offset 162 scaled_channel blendBins[8]; // % // offset 178 scaled_channel blendValues[8]; // need 4 byte alignment // units // offset 186 uint8_t alignmentFill_at_186[2]; }; static_assert(sizeof(blend_table_s) == 188); struct persistent_config_s { // offset 0 engine_configuration_s engineConfiguration; // target TPS value, 0 to 100% // TODO: use int8 data date once we template interpolation method // target TPS position // offset 3760 float etbBiasBins[ETB_BIAS_CURVE_LENGTH]; // PWM bias, 0 to 100% // ETB duty cycle bias // offset 3792 float etbBiasValues[ETB_BIAS_CURVE_LENGTH]; // % // offset 3824 scaled_channel iacPidMultTable[IAC_PID_MULT_SIZE][IAC_PID_MULT_SIZE]; // Load // offset 3888 uint8_t iacPidMultLoadBins[IAC_PID_MULT_SIZE]; // RPM // offset 3896 scaled_channel iacPidMultRpmBins[IAC_PID_MULT_SIZE]; // On Single Coil or Wasted Spark setups you have to lower dwell at high RPM // RPM // offset 3904 uint16_t sparkDwellRpmBins[DWELL_CURVE_SIZE]; // ms // offset 3920 scaled_channel sparkDwellValues[DWELL_CURVE_SIZE]; // CLT-based target RPM for automatic idle controller // C // offset 3936 scaled_channel cltIdleRpmBins[CLT_CURVE_SIZE]; // See idleRpmPid // RPM // offset 3952 scaled_channel cltIdleRpm[CLT_CURVE_SIZE]; // CLT-based timing correction // C // offset 3968 float cltTimingBins[CLT_TIMING_CURVE_SIZE]; // degree // offset 4000 float cltTimingExtra[CLT_TIMING_CURVE_SIZE]; // x // offset 4032 float scriptCurve1Bins[SCRIPT_CURVE_16]; // y // offset 4096 float scriptCurve1[SCRIPT_CURVE_16]; // x // offset 4160 float scriptCurve2Bins[SCRIPT_CURVE_16]; // y // offset 4224 float scriptCurve2[SCRIPT_CURVE_16]; // x // offset 4288 float scriptCurve3Bins[SCRIPT_CURVE_8]; // y // offset 4320 float scriptCurve3[SCRIPT_CURVE_8]; // x // offset 4352 float scriptCurve4Bins[SCRIPT_CURVE_8]; // y // offset 4384 float scriptCurve4[SCRIPT_CURVE_8]; // x // offset 4416 float scriptCurve5Bins[SCRIPT_CURVE_8]; // y // offset 4448 float scriptCurve5[SCRIPT_CURVE_8]; // x // offset 4480 float scriptCurve6Bins[SCRIPT_CURVE_8]; // y // offset 4512 float scriptCurve6[SCRIPT_CURVE_8]; // kPa // offset 4544 float baroCorrPressureBins[BARO_CORR_SIZE]; // RPM // offset 4560 float baroCorrRpmBins[BARO_CORR_SIZE]; // ratio // offset 4576 float baroCorrTable[BARO_CORR_SIZE][BARO_CORR_SIZE]; // Cranking fuel correction coefficient based on TPS // Ratio // offset 4640 float crankingTpsCoef[CRANKING_CURVE_SIZE]; // % // offset 4672 float crankingTpsBins[CRANKING_CURVE_SIZE]; // Optional timing advance table for Cranking (see useSeparateAdvanceForCranking) // RPM // offset 4704 uint16_t crankingAdvanceBins[CRANKING_ADVANCE_CURVE_SIZE]; // Optional timing advance table for Cranking (see useSeparateAdvanceForCranking) // deg // offset 4712 scaled_channel crankingAdvance[CRANKING_ADVANCE_CURVE_SIZE]; // RPM-based idle position for coasting // RPM // offset 4720 scaled_channel iacCoastingRpmBins[CLT_CURVE_SIZE]; // RPM-based idle position for coasting // % // offset 4736 scaled_channel iacCoasting[CLT_CURVE_SIZE]; // offset 4752 error_message_t warning_message; // C // offset 4872 float afterstartCoolantBins[AFTERSTART_HOLD_CURVE_SIZE]; // Seconds // offset 4904 float afterstartHoldTime[AFTERSTART_HOLD_CURVE_SIZE]; // % // offset 4936 float afterstartEnrich[AFTERSTART_ENRICH_CURVE_SIZE]; // Seconds // offset 4968 float afterstartDecayTime[AFTERSTART_DECAY_CURVE_SIZE]; // offset 5000 scaled_channel boostTableOpenLoop[BOOST_RPM_COUNT][BOOST_LOAD_COUNT]; // RPM // offset 5064 scaled_channel boostRpmBins[BOOST_RPM_COUNT]; // offset 5072 scaled_channel boostTableClosedLoop[BOOST_RPM_COUNT][BOOST_LOAD_COUNT]; // % // offset 5136 uint8_t boostTpsBins[BOOST_LOAD_COUNT]; // % // offset 5144 uint8_t pedalToTpsTable[PEDAL_TO_TPS_SIZE][PEDAL_TO_TPS_SIZE]; // % // offset 5208 uint8_t pedalToTpsPedalBins[PEDAL_TO_TPS_SIZE]; // RPM // offset 5216 scaled_channel pedalToTpsRpmBins[PEDAL_TO_TPS_SIZE]; // CLT-based cranking position multiplier for simple manual idle controller // C // offset 5224 float cltCrankingCorrBins[CLT_CRANKING_CURVE_SIZE]; // CLT-based cranking position multiplier for simple manual idle controller // % // offset 5256 float cltCrankingCorr[CLT_CRANKING_CURVE_SIZE]; // Optional timing advance table for Idle (see useSeparateAdvanceForIdle) // RPM // offset 5288 scaled_channel idleAdvanceBins[IDLE_ADVANCE_CURVE_SIZE]; // Optional timing advance table for Idle (see useSeparateAdvanceForIdle) // deg // offset 5296 float idleAdvance[IDLE_ADVANCE_CURVE_SIZE]; // RPM // offset 5328 scaled_channel idleVeRpmBins[IDLE_VE_SIZE]; // load // offset 5332 uint8_t idleVeLoadBins[IDLE_VE_SIZE]; // % // offset 5336 scaled_channel idleVeTable[IDLE_VE_SIZE][IDLE_VE_SIZE]; // offset 5368 lua_script_t luaScript; // C // offset 13368 float cltFuelCorrBins[CLT_CURVE_SIZE]; // ratio // offset 13432 float cltFuelCorr[CLT_CURVE_SIZE]; // C // offset 13496 float iatFuelCorrBins[IAT_CURVE_SIZE]; // ratio // offset 13560 float iatFuelCorr[IAT_CURVE_SIZE]; // ratio // offset 13624 float crankingFuelCoef[CRANKING_CURVE_SIZE]; // C // offset 13656 float crankingFuelBins[CRANKING_CURVE_SIZE]; // ratio // offset 13688 float crankingCycleCoef[CRANKING_CURVE_SIZE]; // counter // offset 13720 float crankingCycleBins[CRANKING_CURVE_SIZE]; // CLT-based idle position multiplier for simple manual idle controller // C // offset 13752 float cltIdleCorrBins[CLT_CURVE_SIZE]; // CLT-based idle position multiplier for simple manual idle controller // ratio // offset 13816 float cltIdleCorr[CLT_CURVE_SIZE]; // Also known as MAF transfer function. // kg/hour value. // By the way 2.081989116 kg/h = 1 ft3/m // kg/hour // offset 13880 float mafDecoding[MAF_DECODING_COUNT]; // V // offset 14904 float mafDecodingBins[MAF_DECODING_COUNT]; // deg // offset 15928 scaled_channel ignitionIatCorrTable[8][8]; // C // offset 15992 int8_t ignitionIatCorrTempBins[8]; // Load // offset 16000 scaled_channel ignitionIatCorrLoadBins[8]; // deg // offset 16008 int16_t injectionPhase[IGN_RPM_COUNT][IGN_LOAD_COUNT]; // Load // offset 16520 uint16_t injPhaseLoadBins[FUEL_LOAD_COUNT]; // RPM // offset 16552 uint16_t injPhaseRpmBins[FUEL_RPM_COUNT]; // onoff // offset 16584 uint8_t tcuSolenoidTable[TCU_SOLENOID_COUNT][TCU_GEAR_COUNT]; // kPa // offset 16644 scaled_channel mapEstimateTable[FUEL_RPM_COUNT][FUEL_LOAD_COUNT]; // % TPS // offset 17156 scaled_channel mapEstimateTpsBins[FUEL_LOAD_COUNT]; // RPM // offset 17188 uint16_t mapEstimateRpmBins[FUEL_RPM_COUNT]; // value // offset 17220 int8_t vvtTable1[SCRIPT_TABLE_8][SCRIPT_TABLE_8]; // L // offset 17284 uint16_t vvtTable1LoadBins[SCRIPT_TABLE_8]; // RPM // offset 17300 uint16_t vvtTable1RpmBins[SCRIPT_TABLE_8]; // value // offset 17316 int8_t vvtTable2[SCRIPT_TABLE_8][SCRIPT_TABLE_8]; // L // offset 17380 uint16_t vvtTable2LoadBins[SCRIPT_TABLE_8]; // RPM // offset 17396 uint16_t vvtTable2RpmBins[SCRIPT_TABLE_8]; // deg // offset 17412 scaled_channel ignitionTable[IGN_RPM_COUNT][IGN_LOAD_COUNT]; // Load // offset 17924 uint16_t ignitionLoadBins[IGN_LOAD_COUNT]; // RPM // offset 17956 uint16_t ignitionRpmBins[IGN_RPM_COUNT]; // % // offset 17988 scaled_channel veTable[FUEL_RPM_COUNT][FUEL_LOAD_COUNT]; // kPa // offset 18500 uint16_t veLoadBins[FUEL_LOAD_COUNT]; // RPM // offset 18532 uint16_t veRpmBins[FUEL_RPM_COUNT]; // lambda // offset 18564 scaled_channel lambdaTable[FUEL_RPM_COUNT][FUEL_LOAD_COUNT]; // offset 18820 uint16_t lambdaLoadBins[FUEL_LOAD_COUNT]; // RPM // offset 18852 uint16_t lambdaRpmBins[FUEL_RPM_COUNT]; // value // offset 18884 float tpsTpsAccelTable[TPS_TPS_ACCEL_TABLE][TPS_TPS_ACCEL_TABLE]; // from // offset 19140 float tpsTpsAccelFromRpmBins[TPS_TPS_ACCEL_TABLE]; // to // offset 19172 float tpsTpsAccelToRpmBins[TPS_TPS_ACCEL_TABLE]; // value // offset 19204 float scriptTable1[SCRIPT_TABLE_8][SCRIPT_TABLE_8]; // L // offset 19460 int16_t scriptTable1LoadBins[SCRIPT_TABLE_8]; // RPM // offset 19476 int16_t scriptTable1RpmBins[SCRIPT_TABLE_8]; // value // offset 19492 uint8_t scriptTable2[SCRIPT_TABLE_8][SCRIPT_TABLE_8]; // L // offset 19556 int16_t scriptTable2LoadBins[SCRIPT_TABLE_8]; // RPM // offset 19572 int16_t scriptTable2RpmBins[SCRIPT_TABLE_8]; // value // offset 19588 uint8_t scriptTable3[SCRIPT_TABLE_8][SCRIPT_TABLE_8]; // L // offset 19652 int16_t scriptTable3LoadBins[SCRIPT_TABLE_8]; // RPM // offset 19668 int16_t scriptTable3RpmBins[SCRIPT_TABLE_8]; // value // offset 19684 uint8_t scriptTable4[SCRIPT_TABLE_8][SCRIPT_TABLE_8]; // L // offset 19748 int16_t scriptTable4LoadBins[SCRIPT_TABLE_8]; // RPM // offset 19764 int16_t scriptTable4RpmBins[SCRIPT_TABLE_8]; // offset 19780 uint16_t ignTrimLoadBins[TRIM_SIZE]; // rpm // offset 19788 uint16_t ignTrimRpmBins[TRIM_SIZE]; // offset 19796 cyl_trim_s ignTrims[12]; // offset 19988 uint16_t fuelTrimLoadBins[TRIM_SIZE]; // rpm // offset 19996 uint16_t fuelTrimRpmBins[TRIM_SIZE]; // offset 20004 cyl_trim_s fuelTrims[12]; // ratio // offset 20196 scaled_channel crankingFuelCoefE100[CRANKING_CURVE_SIZE]; // Airmass // offset 20212 scaled_channel tcu_pcAirmassBins[TCU_MAGIC_SIZE]; // % // offset 20220 uint8_t tcu_pcValsR[TCU_MAGIC_SIZE]; // % // offset 20228 uint8_t tcu_pcValsN[TCU_MAGIC_SIZE]; // % // offset 20236 uint8_t tcu_pcVals1[TCU_MAGIC_SIZE]; // % // offset 20244 uint8_t tcu_pcVals2[TCU_MAGIC_SIZE]; // % // offset 20252 uint8_t tcu_pcVals3[TCU_MAGIC_SIZE]; // % // offset 20260 uint8_t tcu_pcVals4[TCU_MAGIC_SIZE]; // % // offset 20268 uint8_t tcu_pcVals12[TCU_MAGIC_SIZE]; // % // offset 20276 uint8_t tcu_pcVals23[TCU_MAGIC_SIZE]; // % // offset 20284 uint8_t tcu_pcVals34[TCU_MAGIC_SIZE]; // % // offset 20292 uint8_t tcu_pcVals21[TCU_MAGIC_SIZE]; // % // offset 20300 uint8_t tcu_pcVals32[TCU_MAGIC_SIZE]; // % // offset 20308 uint8_t tcu_pcVals43[TCU_MAGIC_SIZE]; // TPS // offset 20316 uint8_t tcu_tccTpsBins[8]; // MPH // offset 20324 uint8_t tcu_tccLockSpeed[8]; // MPH // offset 20332 uint8_t tcu_tccUnlockSpeed[8]; // KPH // offset 20340 uint8_t tcu_32SpeedBins[8]; // % // offset 20348 uint8_t tcu_32Vals[8]; // % // offset 20356 scaled_channel throttle2TrimTable[6][6]; // % // offset 20392 uint8_t throttle2TrimTpsBins[6]; // RPM // offset 20398 scaled_channel throttle2TrimRpmBins[6]; // deg // offset 20404 scaled_channel maxKnockRetardTable[6][6]; // % // offset 20440 uint8_t maxKnockRetardLoadBins[6]; // RPM // offset 20446 scaled_channel maxKnockRetardRpmBins[6]; // deg // offset 20452 scaled_channel ALSTimingRetardTable[4][4]; // TPS // offset 20484 uint16_t alsIgnRetardLoadBins[4]; // RPM // offset 20492 uint16_t alsIgnRetardrpmBins[4]; // percent // offset 20500 scaled_channel ALSFuelAdjustment[4][4]; // TPS // offset 20532 uint16_t alsFuelAdjustmentLoadBins[4]; // RPM // offset 20540 uint16_t alsFuelAdjustmentrpmBins[4]; // offset 20548 blend_table_s ignBlends[IGN_BLEND_COUNT]; // offset 21300 blend_table_s veBlends[VE_BLEND_COUNT]; // % // offset 22052 scaled_channel throttleEstimateEffectiveAreaBins[12]; // In units of g/s normalized to choked flow conditions // g/s // offset 22076 scaled_channel throttleEstimateEffectiveAreaValues[12]; // offset 22100 blend_table_s boostOpenLoopBlends[BOOST_BLEND_COUNT]; // offset 22476 blend_table_s boostClosedLoopBlends[BOOST_BLEND_COUNT]; }; static_assert(sizeof(persistent_config_s) == 22852);