# IT-AUTOFLIGHT System Controller V4.0.5 # Copyright (c) 2020 Joshua Davidson (Octal450) setprop("/it-autoflight/config/tuning-mode", 0); # Not used by controller # Initialize all used variables and property nodes # Sim var Controls = { aileron: props.globals.getNode("/controls/flight/aileron", 1), elevator: props.globals.getNode("/controls/flight/elevator", 1), rudder: props.globals.getNode("/controls/flight/rudder", 1), }; var FPLN = { active: props.globals.getNode("/autopilot/route-manager/active", 1), activeTemp: 0, currentCourse: 0, currentWp: props.globals.getNode("/autopilot/route-manager/current-wp", 1), currentWpTemp: 0, deltaAngle: 0, deltaAngleRad: 0, distCoeff: 0, maxBank: 0, maxBankLimit: 0, nextCourse: 0, num: props.globals.getNode("/autopilot/route-manager/route/num", 1), numTemp: 0, R: 0, radius: 0, turnDist: 0, wp0Dist: props.globals.getNode("/autopilot/route-manager/wp/dist", 1), wpFlyFrom: 0, wpFlyTo: 0, }; var Gear = { wow0: props.globals.getNode("/gear/gear[0]/wow", 1), wow1: props.globals.getNode("/gear/gear[1]/wow", 1), wow1Temp: 1, wow2: props.globals.getNode("/gear/gear[2]/wow", 1), wow2Temp: 1, }; var Misc = { efis0Trk: props.globals.getNode("/instrumentation/efis[0]/hdg-trk-selected", 1), efis1Trk: props.globals.getNode("/instrumentation/efis[1]/hdg-trk-selected", 1), flapNorm: props.globals.getNode("/surface-positions/flap-pos-norm", 1), }; var Position = { gearAglFtTemp: 0, gearAglFt: props.globals.getNode("/position/gear-agl-ft", 1), indicatedAltitudeFt: props.globals.getNode("/instrumentation/altimeter/indicated-altitude-ft", 1), indicatedAltitudeFtTemp: 0, }; var Radio = { gsDefl: [props.globals.getNode("/instrumentation/nav[0]/gs-needle-deflection-norm", 1), props.globals.getNode("/instrumentation/nav[1]/gs-needle-deflection-norm", 1)], gsDeflTemp: 0, inRange: [props.globals.getNode("/instrumentation/nav[0]/in-range", 1), props.globals.getNode("/instrumentation/nav[1]/in-range", 1)], inRangeTemp: 0, locDefl: [props.globals.getNode("/instrumentation/nav[0]/heading-needle-deflection-norm", 1), props.globals.getNode("/instrumentation/nav[1]/heading-needle-deflection-norm", 1)], locDeflTemp: 0, radioSel: 0, signalQuality: [props.globals.getNode("/instrumentation/nav[0]/signal-quality-norm", 1), props.globals.getNode("/instrumentation/nav[1]/signal-quality-norm", 1)], signalQualityTemp: 0, }; var Velocities = { airspeedKt: props.globals.getNode("/velocities/airspeed-kt", 1), # Only used for gain scheduling groundspeedKt: props.globals.getNode("/velocities/groundspeed-kt", 1), groundspeedMps: 0, indicatedAirspeedKt: props.globals.getNode("/instrumentation/airspeed-indicator/indicated-speed-kt", 1), indicatedMach: props.globals.getNode("/instrumentation/airspeed-indicator/indicated-mach", 1), trueAirspeedKt: props.globals.getNode("/instrumentation/airspeed-indicator/true-speed-kt", 1), trueAirspeedKtTemp: 0, }; # IT-AUTOFLIGHT var Input = { alt: props.globals.initNode("/it-autoflight/input/alt", 10000, "INT"), ap1: props.globals.initNode("/it-autoflight/input/ap1", 0, "BOOL"), ap2: props.globals.initNode("/it-autoflight/input/ap2", 0, "BOOL"), athr: props.globals.initNode("/it-autoflight/input/athr", 0, "BOOL"), altDiff: 0, bankLimitSW: props.globals.initNode("/it-autoflight/input/bank-limit-sw", 0, "INT"), bankLimitSWTemp: 0, fd1: props.globals.initNode("/it-autoflight/input/fd1", 0, "BOOL"), fd2: props.globals.initNode("/it-autoflight/input/fd2", 0, "BOOL"), fpa: props.globals.initNode("/it-autoflight/input/fpa", 0, "DOUBLE"), fpaAbs: props.globals.initNode("/it-autoflight/input/fpa-abs", 0, "DOUBLE"), # Set by property rule hdg: props.globals.initNode("/it-autoflight/input/hdg", 0, "INT"), hdgCalc: 0, kts: props.globals.initNode("/it-autoflight/input/kts", 250, "INT"), ktsMach: props.globals.initNode("/it-autoflight/input/kts-mach", 0, "BOOL"), lat: props.globals.initNode("/it-autoflight/input/lat", 5, "INT"), latTemp: 5, mach: props.globals.initNode("/it-autoflight/input/mach", 0.5, "DOUBLE"), toga: props.globals.initNode("/it-autoflight/input/toga", 0, "BOOL"), trk: props.globals.initNode("/it-autoflight/input/trk", 0, "BOOL"), trueCourse: props.globals.initNode("/it-autoflight/input/true-course", 0, "BOOL"), useNav2Radio: props.globals.initNode("/it-autoflight/input/use-nav2-radio", 0, "BOOL"), vs: props.globals.initNode("/it-autoflight/input/vs", 0, "INT"), vsAbs: props.globals.initNode("/it-autoflight/input/vs-abs", 0, "INT"), # Set by property rule vert: props.globals.initNode("/it-autoflight/input/vert", 7, "INT"), vertTemp: 7, }; var Internal = { alt: props.globals.initNode("/it-autoflight/internal/alt", 10000, "INT"), altCaptureActive: 0, altDiff: 0, altTemp: 0, altPredicted: props.globals.initNode("/it-autoflight/internal/altitude-predicted", 0, "DOUBLE"), bankLimit: props.globals.initNode("/it-autoflight/internal/bank-limit", 30, "INT"), bankLimitAuto: 30, captVs: 0, driftAngle: props.globals.initNode("/it-autoflight/internal/drift-angle-deg", 0, "DOUBLE"), flchActive: 0, fpa: props.globals.initNode("/it-autoflight/internal/fpa", 0, "DOUBLE"), hdgErrorDeg: props.globals.initNode("/it-autoflight/internal/heading-error-deg", 0, "DOUBLE"), hdgHldValue: 360, hdgPredicted: props.globals.initNode("/it-autoflight/internal/heading-predicted", 0, "DOUBLE"), lnavAdvanceNm: props.globals.initNode("/it-autoflight/internal/lnav-advance-nm", 0, "DOUBLE"), minVs: props.globals.initNode("/it-autoflight/internal/min-vs", -500, "INT"), maxVs: props.globals.initNode("/it-autoflight/internal/max-vs", 500, "INT"), vs: props.globals.initNode("/it-autoflight/internal/vert-speed-fpm", 0, "DOUBLE"), vsTemp: 0, }; var Output = { ap1: props.globals.initNode("/it-autoflight/output/ap1", 0, "BOOL"), ap1Temp: 0, ap2: props.globals.initNode("/it-autoflight/output/ap2", 0, "BOOL"), ap2Temp: 0, apprArm: props.globals.initNode("/it-autoflight/output/appr-armed", 0, "BOOL"), athr: props.globals.initNode("/it-autoflight/output/athr", 0, "BOOL"), athrTemp: 0, fd1: props.globals.initNode("/it-autoflight/output/fd1", 0, "BOOL"), fd1Temp: 0, fd2: props.globals.initNode("/it-autoflight/output/fd2", 0, "BOOL"), fd2Temp: 0, hdgInHld: props.globals.initNode("/it-autoflight/output/hdg-in-hld", 0, "BOOL"), hdgInHldTemp: 0, lat: props.globals.initNode("/it-autoflight/output/lat", 5, "INT"), latTemp: 5, lnavArm: props.globals.initNode("/it-autoflight/output/lnav-armed", 0, "BOOL"), locArm: props.globals.initNode("/it-autoflight/output/loc-armed", 0, "BOOL"), thrMode: props.globals.initNode("/it-autoflight/output/thr-mode", 2, "INT"), vert: props.globals.initNode("/it-autoflight/output/vert", 7, "INT"), vertTemp: 7, }; var Text = { arm: props.globals.initNode("/it-autoflight/mode/arm", " ", "STRING"), lat: props.globals.initNode("/it-autoflight/mode/lat", "T/O", "STRING"), thr: props.globals.initNode("/it-autoflight/mode/thr", "PITCH", "STRING"), vert: props.globals.initNode("/it-autoflight/mode/vert", "T/O CLB", "STRING"), vertTemp: "T/O CLB", }; var Setting = { autoBankMaxDeg: props.globals.getNode("/it-autoflight/settings/auto-bank-max-deg", 1), autolandWithoutAp: props.globals.getNode("/it-autoflight/settings/autoland-without-ap", 1), autolandWithoutApTemp: 0, disableFinal: props.globals.getNode("/it-autoflight/settings/disable-final", 1), latAglFt: props.globals.getNode("/it-autoflight/settings/lat-agl-ft", 1), landingFlap: props.globals.getNode("/it-autoflight/settings/land-flap", 1), reducAglFt: props.globals.getNode("/it-autoflight/settings/reduc-agl-ft", 1), retardAltitude: props.globals.getNode("/it-autoflight/settings/retard-ft", 1), retardEnable: props.globals.getNode("/it-autoflight/settings/retard-enable", 1), togaSpd: props.globals.getNode("/it-autoflight/settings/togaspd", 1), }; var Sound = { apOff: props.globals.initNode("/it-autoflight/sound/apoffsound", 0, "BOOL"), enableApOff: 0, }; var Gain = { altGain: props.globals.getNode("/it-autoflight/config/cmd/alt-gain", 1), hdgGain: props.globals.getNode("/it-autoflight/config/cmd/roll", 1), pitchKp: props.globals.initNode("/it-autoflight/config/pitch/kp", 0, "DOUBLE"), pitchKpCalc: 0, pitchKpLow: props.globals.getNode("/it-autoflight/config/pitch/kp-low", 1), pitchKpLowTemp: 0, pitchKpHigh: props.globals.getNode("/it-autoflight/config/pitch/kp-high", 1), pitchKpHighTemp: 0, rollCmdKp: props.globals.initNode("/it-autoflight/config/cmd/roll-kp", 0, "DOUBLE"), rollCmdKpCalc: 0, rollKp: props.globals.initNode("/it-autoflight/config/roll/kp", 0, "DOUBLE"), rollKpCalc: 0, rollKpLowTemp: 0, rollKpLow: props.globals.getNode("/it-autoflight/config/roll/kp-low", 1), rollKpHighTemp: 0, rollKpHigh: props.globals.getNode("/it-autoflight/config/roll/kp-high", 1), }; var ITAF = { init: func() { Input.ktsMach.setBoolValue(0); Input.ap1.setBoolValue(0); Input.ap2.setBoolValue(0); Input.athr.setBoolValue(0); Input.fd1.setBoolValue(0); Input.fd2.setBoolValue(0); Input.hdg.setValue(360); Input.alt.setValue(10000); Input.vs.setValue(0); Input.fpa.setValue(0); Input.lat.setValue(5); Input.vert.setValue(7); Input.trk.setBoolValue(0); Input.trueCourse.setBoolValue(0); Input.toga.setBoolValue(0); Input.bankLimitSW.setValue(0); Input.useNav2Radio.setBoolValue(0); Output.ap1.setBoolValue(0); Output.ap2.setBoolValue(0); Output.athr.setBoolValue(0); Output.fd1.setBoolValue(0); Output.fd2.setBoolValue(0); Output.hdgInHld.setBoolValue(0); Output.lnavArm.setBoolValue(0); Output.locArm.setBoolValue(0); Output.apprArm.setBoolValue(0); Output.thrMode.setValue(0); Output.lat.setValue(5); Output.vert.setValue(7); Internal.minVs.setValue(-500); Internal.maxVs.setValue(500); Internal.bankLimit.setValue(30); Internal.bankLimitAuto = 30; Internal.alt.setValue(10000); Internal.altCaptureActive = 0; Input.kts.setValue(250); Input.mach.setValue(0.5); Text.thr.setValue("PITCH"); Text.arm.setValue(" "); Text.lat.setValue("T/O"); Text.vert.setValue("T/O CLB"); loopTimer.start(); slowLoopTimer.start(); }, loop: func() { Output.latTemp = Output.lat.getValue(); Output.vertTemp = Output.vert.getValue(); Output.ap1Temp = Output.ap1.getBoolValue(); Output.ap2Temp = Output.ap2.getBoolValue(); Setting.autolandWithoutApTemp = Setting.autolandWithoutAp.getBoolValue(); # Kill Autoland if the system should not autoland without AP, and AP is off if (Setting.autolandWithoutApTemp) { # Only evaluate the rest if this setting is on if (!Output.ap1Temp and !Output.ap2Temp) { if (Output.latTemp == 4) { me.activateLOC(); } if (Output.vertTemp == 6) { me.activateGS(); } } } # VOR/ILS Revision if (Output.latTemp == 2 or Output.latTemp == 4 or Output.vertTemp == 2 or Output.vertTemp == 6) { me.checkRadioRevision(Output.latTemp, Output.vertTemp); } Gear.wow1Temp = Gear.wow1.getBoolValue(); Gear.wow2Temp = Gear.wow2.getBoolValue(); Output.latTemp = Output.lat.getValue(); Output.vertTemp = Output.vert.getValue(); Text.vertTemp = Text.vert.getValue(); Position.gearAglFtTemp = Position.gearAglFt.getValue(); Internal.vsTemp = Internal.vs.getValue(); Position.indicatedAltitudeFtTemp = Position.indicatedAltitudeFt.getValue(); Output.hdgInHldTemp = Output.hdgInHld.getBoolValue(); # HDG HLD logic if (Output.latTemp == 0) { if (Input.hdg.getValue() == Internal.hdgHldValue and abs(Internal.hdgErrorDeg.getValue()) <= 2.5) { if (Output.hdgInHldTemp != 1) { Output.hdgInHld.setBoolValue(1); } } else if (Input.hdg.getValue() != Internal.hdgHldValue) { Internal.hdgHldValue = Input.hdg.getValue(); if (Output.hdgInHldTemp != 0 and abs(Internal.hdgErrorDeg.getValue()) > 2.5) { Output.hdgInHld.setBoolValue(0); } } } else { if (Output.hdgInHldTemp != 0) { Output.hdgInHld.setBoolValue(0); } } # LNAV Engagement if (Output.lnavArm.getBoolValue()) { me.checkLNAV(1); } # VOR/LOC or ILS/LOC Capture if (Output.locArm.getBoolValue()) { me.checkLOC(1, 0); } # G/S Capture if (Output.apprArm.getBoolValue()) { me.checkAPPR(1); } # Autoland Logic if (Output.latTemp == 2) { if (Position.gearAglFtTemp <= 150) { if (Output.ap1Temp or Output.ap2Temp or Setting.autolandWithoutApTemp) { me.setLatMode(4); } } } if (Output.vertTemp == 2) { if (Position.gearAglFtTemp <= 100 and Position.gearAglFtTemp >= 5) { if (Output.ap1Temp or Output.ap2Temp or Setting.autolandWithoutApTemp) { me.setVertMode(6); } } } else if (Output.vertTemp == 6) { if (!Output.ap1Temp and !Output.ap2Temp and !Setting.autolandWithoutApTemp) { me.activateLOC(); me.activateGS(); } else { if (Position.gearAglFtTemp <= 50 and Position.gearAglFtTemp >= 5) { Text.vert.setValue("FLARE"); } if (Gear.wow1Temp and Gear.wow2Temp) { Text.lat.setValue("RLOU"); Text.vert.setValue("ROLLOUT"); } } } # FLCH Engagement if (Text.vertTemp == "T/O CLB") { me.checkFLCH(Setting.reducAglFt.getValue()); } # Altitude Capture/Sync Logic if (Output.vertTemp != 0) { Internal.alt.setValue(Input.alt.getValue()); } Internal.altTemp = Internal.alt.getValue(); Internal.altDiff = Internal.altTemp - Position.indicatedAltitudeFtTemp; if (Output.vertTemp != 0 and Output.vertTemp != 2 and Output.vertTemp != 6) { Internal.captVs = math.clamp(math.round(abs(Internal.vs.getValue()) / (-1 * Gain.altGain.getValue()), 100), 50, 2500); # Capture limits if (abs(Internal.altDiff) <= Internal.captVs and !Gear.wow1Temp and !Gear.wow2Temp) { if (Internal.altTemp >= Position.indicatedAltitudeFtTemp and Internal.vsTemp >= -25) { # Don't capture if we are going the wrong way me.setVertMode(3); } else if (Internal.altTemp < Position.indicatedAltitudeFtTemp and Internal.vsTemp <= 25) { # Don't capture if we are going the wrong way me.setVertMode(3); } } } # Altitude Hold Min/Max Reset if (Internal.altCaptureActive) { if (abs(Internal.altDiff) <= 25) { me.resetClimbRateLim(); Text.vert.setValue("ALT HLD"); } } # Thrust Mode Selector if (Output.athr.getBoolValue() and Output.vertTemp != 7 and Setting.retardEnable.getBoolValue() and Position.gearAglFt.getValue() <= Setting.retardAltitude.getValue() and Misc.flapNorm.getValue() >= Setting.landingFlap.getValue() - 0.001) { Output.thrMode.setValue(1); Text.thr.setValue("RETARD"); if (Gear.wow1Temp or Gear.wow2Temp) { # Disconnect A/THR on either main gear touch me.athrMaster(0); setprop("/controls/engines/engine[0]/throttle", 0); setprop("/controls/engines/engine[1]/throttle", 0); setprop("/controls/engines/engine[2]/throttle", 0); setprop("/controls/engines/engine[3]/throttle", 0); setprop("/controls/engines/engine[4]/throttle", 0); setprop("/controls/engines/engine[5]/throttle", 0); setprop("/controls/engines/engine[6]/throttle", 0); setprop("/controls/engines/engine[7]/throttle", 0); } } else if (Output.vertTemp == 4) { if (Internal.altTemp >= Position.indicatedAltitudeFtTemp) { Output.thrMode.setValue(2); Text.thr.setValue("PITCH"); if (Internal.flchActive) { # Set before mode change to prevent it from overwriting by mistake Text.vert.setValue("SPD CLB"); } } else { Output.thrMode.setValue(1); Text.thr.setValue("PITCH"); if (Internal.flchActive) { # Set before mode change to prevent it from overwriting by mistake Text.vert.setValue("SPD DES"); } } } else if (Output.vertTemp == 7) { Output.thrMode.setValue(2); Text.thr.setValue("PITCH"); } else { Output.thrMode.setValue(0); Text.thr.setValue("THRUST"); } }, slowLoop: func() { Input.bankLimitSWTemp = Input.bankLimitSW.getValue(); Velocities.trueAirspeedKtTemp = Velocities.trueAirspeedKt.getValue(); FPLN.activeTemp = FPLN.active.getValue(); FPLN.currentWpTemp = FPLN.currentWp.getValue(); FPLN.numTemp = FPLN.num.getValue(); # Bank Limit if (Velocities.trueAirspeedKtTemp >= 420) { Internal.bankLimitAuto = 15; } else if (Velocities.trueAirspeedKtTemp >= 340) { Internal.bankLimitAuto = 20; } else { Internal.bankLimitAuto = 30; } math.clamp(Internal.bankLimitAuto, 15, Setting.autoBankMaxDeg.getValue()); # Limit to max degree if (Input.bankLimitSWTemp == 0) { Internal.bankLimit.setValue(Internal.bankLimitAuto); } else if (Input.bankLimitSWTemp == 1) { Internal.bankLimit.setValue(5); } else if (Input.bankLimitSWTemp == 2) { Internal.bankLimit.setValue(10); } else if (Input.bankLimitSWTemp == 3) { Internal.bankLimit.setValue(15); } else if (Input.bankLimitSWTemp == 4) { Internal.bankLimit.setValue(20); } else if (Input.bankLimitSWTemp == 5) { Internal.bankLimit.setValue(25); } else if (Input.bankLimitSWTemp == 6) { Internal.bankLimit.setValue(30); } # If in LNAV mode and route is not longer active, switch to HDG HLD if (Output.lat.getValue() == 1) { # Only evaulate the rest of the condition if we are in LNAV mode if (FPLN.num.getValue() == 0 or !FPLN.active.getBoolValue()) { me.setLatMode(3); } } # Waypoint Advance Logic if (FPLN.numTemp > 0 and FPLN.activeTemp == 1) { if ((FPLN.currentWpTemp + 1) < FPLN.numTemp) { Velocities.groundspeedMps = Velocities.groundspeedKt.getValue() * 0.5144444444444; FPLN.wpFlyFrom = FPLN.currentWpTemp; if (FPLN.wpFlyFrom < 0) { FPLN.wpFlyFrom = 0; } FPLN.currentCourse = getprop("/autopilot/route-manager/route/wp[" ~ FPLN.wpFlyFrom ~ "]/leg-bearing-true-deg"); # Best left at getprop FPLN.wpFlyTo = FPLN.currentWpTemp + 1; if (FPLN.wpFlyTo < 0) { FPLN.wpFlyTo = 0; } FPLN.nextCourse = getprop("/autopilot/route-manager/route/wp[" ~ FPLN.wpFlyTo ~ "]/leg-bearing-true-deg"); # Best left at getprop FPLN.maxBankLimit = Internal.bankLimit.getValue(); FPLN.deltaAngle = math.abs(geo.normdeg180(FPLN.currentCourse - FPLN.nextCourse)); FPLN.maxBank = FPLN.deltaAngle * 1.5; if (FPLN.maxBank > FPLN.maxBankLimit) { FPLN.maxBank = FPLN.maxBankLimit; } FPLN.radius = (Velocities.groundspeedMps * Velocities.groundspeedMps) / (9.81 * math.tan(FPLN.maxBank / 57.2957795131)); FPLN.deltaAngleRad = (180 - FPLN.deltaAngle) / 114.5915590262; FPLN.R = FPLN.radius / math.sin(FPLN.deltaAngleRad); FPLN.distCoeff = FPLN.deltaAngle * -0.011111 + 2; if (FPLN.distCoeff < 1) { FPLN.distCoeff = 1; } FPLN.turnDist = math.cos(FPLN.deltaAngleRad) * FPLN.R * FPLN.distCoeff / 1852; if (Gear.wow0.getBoolValue() and FPLN.turnDist < 1) { FPLN.turnDist = 1; } Internal.lnavAdvanceNm.setValue(FPLN.turnDist); if (FPLN.wp0Dist.getValue() <= FPLN.turnDist and flightplan().getWP(FPLN.currentWp.getValue()).fly_type == "flyBy") { # Don't care unless we are flyBy-ing FPLN.currentWp.setValue(FPLN.currentWpTemp + 1); } } } # Reset system once flight complete if (!Output.ap1.getBoolValue() and !Output.ap2.getBoolValue() and Gear.wow0.getBoolValue() and Velocities.groundspeedKt.getValue() < 60 and Output.vert.getValue() != 7) { # Not in T/O or G/A me.init(); } # Calculate Roll and Pitch Rate Kp if (!Setting.disableFinal.getBoolValue()) { Gain.rollKpLowTemp = Gain.rollKpLow.getValue(); Gain.rollKpHighTemp = Gain.rollKpHigh.getValue(); Gain.pitchKpLowTemp = Gain.pitchKpLow.getValue(); Gain.pitchKpHighTemp = Gain.pitchKpHigh.getValue(); Gain.rollKpCalc = Gain.rollKpLowTemp + (Velocities.airspeedKt.getValue() - 140) * ((Gain.rollKpHighTemp - Gain.rollKpLowTemp) / (360 - 140)); Gain.pitchKpCalc = Gain.pitchKpLowTemp + (Velocities.airspeedKt.getValue() - 140) * ((Gain.pitchKpHighTemp - Gain.pitchKpLowTemp) / (360 - 140)); if (Gain.rollKpLowTemp > Gain.rollKpHighTemp) { Gain.rollKpCalc = math.clamp(Gain.rollKpCalc, Gain.rollKpHighTemp, Gain.rollKpLowTemp); } else if (Gain.rollKpLowTemp < Gain.rollKpHighTemp) { Gain.rollKpCalc = math.clamp(Gain.rollKpCalc, Gain.rollKpLowTemp, Gain.rollKpHighTemp); } if (Gain.pitchKpLowTemp > Gain.pitchKpHighTemp) { Gain.pitchKpCalc = math.clamp(Gain.pitchKpCalc, Gain.pitchKpHighTemp, Gain.pitchKpLowTemp); } else if (Gain.pitchKpLowTemp < Gain.pitchKpHighTemp) { Gain.pitchKpCalc = math.clamp(Gain.pitchKpCalc, Gain.pitchKpLowTemp, Gain.pitchKpHighTemp); } Gain.rollKp.setValue(Gain.rollKpCalc); Gain.pitchKp.setValue(Gain.pitchKpCalc); } # Calculate Roll Command Kp Gain.rollCmdKpCalc = Gain.hdgGain.getValue() + (Velocities.airspeedKt.getValue() - 140) * ((Gain.hdgGain.getValue() + 1.0 - Gain.hdgGain.getValue()) / (360 - 140)); Gain.rollCmdKpCalc = math.clamp(Gain.rollCmdKpCalc, Gain.hdgGain.getValue(), Gain.hdgGain.getValue() + 1.0); Gain.rollCmdKp.setValue(Gain.rollCmdKpCalc); }, ap1Master: func(s) { if (s == 1) { if (Output.vert.getValue() != 6 and !Gear.wow1.getBoolValue() and !Gear.wow2.getBoolValue()) { Controls.rudder.setValue(0); Output.ap1.setBoolValue(1); Sound.enableApOff = 1; Sound.apOff.setBoolValue(0); } } else { Output.ap1.setBoolValue(0); me.apOffFunction(); } Output.ap1Temp = Output.ap1.getBoolValue(); if (Input.ap1.getBoolValue() != Output.ap1Temp) { Input.ap1.setBoolValue(Output.ap1Temp); } }, ap2Master: func(s) { if (s == 1) { if (Output.vert.getValue() != 6 and !Gear.wow1.getBoolValue() and !Gear.wow2.getBoolValue()) { Controls.rudder.setValue(0); Output.ap2.setBoolValue(1); Sound.enableApOff = 1; Sound.apOff.setBoolValue(0); } } else { Output.ap2.setBoolValue(0); me.apOffFunction(); } Output.ap2Temp = Output.ap2.getBoolValue(); if (Input.ap2.getBoolValue() != Output.ap2Temp) { Input.ap2.setBoolValue(Output.ap2Temp); } }, apOffFunction: func() { if (!Output.ap1.getBoolValue() and !Output.ap2.getBoolValue()) { # Only do if both APs are off if (!Setting.disableFinal.getBoolValue()) { Controls.aileron.setValue(0); Controls.elevator.setValue(0); Controls.rudder.setValue(0); } if (Text.vert.getValue() == "ROLLOUT") { me.init(1); } if (Sound.enableApOff) { Sound.apOff.setBoolValue(1); Sound.enableApOff = 0; } } }, athrMaster: func(s) { if (s == 1) { Output.athr.setBoolValue(1); } else { Output.athr.setBoolValue(0); } Output.athrTemp = Output.athr.getBoolValue(); if (Input.athr.getBoolValue() != Output.athrTemp) { Input.athr.setBoolValue(Output.athrTemp); } }, fd1Master: func(s) { if (s == 1) { Output.fd1.setBoolValue(1); } else { Output.fd1.setBoolValue(0); } Output.fd1Temp = Output.fd1.getBoolValue(); if (Input.fd1.getBoolValue() != Output.fd1Temp) { Input.fd1.setBoolValue(Output.fd1Temp); } }, fd2Master: func(s) { if (s == 1) { Output.fd2.setBoolValue(1); } else { Output.fd2.setBoolValue(0); } Output.fd2Temp = Output.fd2.getBoolValue(); if (Input.fd2.getBoolValue() != Output.fd2Temp) { Input.fd2.setBoolValue(Output.fd2Temp); } }, setLatMode: func(n) { Output.vertTemp = Output.vert.getValue(); if (n == 0) { # HDG SEL Output.lnavArm.setBoolValue(0); Output.locArm.setBoolValue(0); Output.apprArm.setBoolValue(0); Output.lat.setValue(0); Text.lat.setValue("HDG"); if (Output.vertTemp == 2 or Output.vertTemp == 6) { # Also cancel G/S or FLARE if active me.setVertMode(1); } else { me.armTextCheck(); } } else if (n == 1) { # LNAV me.checkLNAV(0); } else if (n == 2) { # VOR/LOC Output.lnavArm.setBoolValue(0); me.armTextCheck(); me.checkLOC(0, 0); } else if (n == 3) { # HDG HLD Output.lnavArm.setBoolValue(0); Output.locArm.setBoolValue(0); Output.apprArm.setBoolValue(0); me.syncHdg(); Output.lat.setValue(0); Text.lat.setValue("HDG"); Internal.hdgHldValue = Input.hdg.getValue(); Output.hdgInHld.setBoolValue(1); if (Output.vertTemp == 2 or Output.vertTemp == 6) { # Also cancel G/S or FLARE if active me.setVertMode(1); } else { me.armTextCheck(); } } else if (n == 4) { # ALIGN Output.lnavArm.setBoolValue(0); Output.locArm.setBoolValue(0); Output.apprArm.setBoolValue(0); Output.lat.setValue(4); Text.lat.setValue("ALGN"); me.armTextCheck(); } else if (n == 5) { # T/O Output.lnavArm.setBoolValue(0); Output.locArm.setBoolValue(0); Output.apprArm.setBoolValue(0); Output.lat.setValue(5); Text.lat.setValue("T/O"); me.armTextCheck(); } }, setLatArm: func(n) { if (n == 0) { Output.lnavArm.setBoolValue(0); me.armTextCheck(); } else if (n == 1) { if (FPLN.num.getValue() > 0 and FPLN.active.getBoolValue()) { Output.lnavArm.setBoolValue(1); me.armTextCheck(); } } else if (n == 3) { me.syncHdg(); Output.lnavArm.setBoolValue(0); me.armTextCheck(); } }, setVertMode: func(n) { Input.altDiff = Input.alt.getValue() - Position.indicatedAltitudeFt.getValue(); if (n == 0) { # ALT HLD Internal.flchActive = 0; Internal.altCaptureActive = 0; Output.apprArm.setBoolValue(0); Output.vert.setValue(0); me.resetClimbRateLim(); Text.vert.setValue("ALT HLD"); me.syncAlt(); me.armTextCheck(); } else if (n == 1) { # V/S if (abs(Input.altDiff) >= 25) { Internal.flchActive = 0; Internal.altCaptureActive = 0; Output.apprArm.setBoolValue(0); Output.vert.setValue(1); Text.vert.setValue("V/S"); me.syncVs(); me.armTextCheck(); } else { Output.apprArm.setBoolValue(0); me.armTextCheck(); } } else if (n == 2) { # G/S me.checkLOC(0, 1); me.checkAPPR(0); } else if (n == 3) { # ALT CAP Internal.flchActive = 0; Output.vert.setValue(0); me.setClimbRateLim(); Internal.altCaptureActive = 1; Text.vert.setValue("ALT CAP"); } else if (n == 4) { # FLCH Output.apprArm.setBoolValue(0); if (abs(Input.altDiff) >= 125) { # SPD CLB or SPD DES if (Input.alt.getValue() >= Position.indicatedAltitudeFt.getValue()) { # Usually set Thrust Mode Selector, but we do it now due to timer lag Text.vert.setValue("SPD CLB"); } else { Text.vert.setValue("SPD DES"); } Internal.altCaptureActive = 0; Output.vert.setValue(4); Internal.flchActive = 1; } else { # ALT CAP Internal.flchActive = 0; Internal.alt.setValue(Input.alt.getValue()); Internal.altCaptureActive = 1; Output.vert.setValue(0); Text.vert.setValue("ALT CAP"); } me.armTextCheck(); } else if (n == 5) { # FPA if (abs(Input.altDiff) >= 25) { Internal.flchActive = 0; Internal.altCaptureActive = 0; Output.apprArm.setBoolValue(0); Output.vert.setValue(5); Text.vert.setValue("FPA"); me.syncFpa(); me.armTextCheck(); } else { Output.apprArm.setBoolValue(0); me.armTextCheck(); } } else if (n == 6) { # FLARE/ROLLOUT Internal.flchActive = 0; Internal.altCaptureActive = 0; Output.apprArm.setBoolValue(0); Output.vert.setValue(6); Text.vert.setValue("G/S"); me.armTextCheck(); } else if (n == 7) { # T/O CLB or G/A CLB, text is set by TOGA selector Internal.flchActive = 0; Internal.altCaptureActive = 0; Output.apprArm.setBoolValue(0); Output.vert.setValue(7); me.armTextCheck(); } }, activateLNAV: func() { if (Output.lat.getValue() != 1) { Output.lnavArm.setBoolValue(0); Output.locArm.setBoolValue(0); Output.apprArm.setBoolValue(0); Output.lat.setValue(1); Text.lat.setValue("LNAV"); if (Output.vertTemp == 2 or Output.vertTemp == 6) { # Also cancel G/S or FLARE if active me.setVertMode(1); } else { me.armTextCheck(); } } }, activateLOC: func() { if (Output.lat.getValue() != 2) { Output.lnavArm.setBoolValue(0); Output.locArm.setBoolValue(0); Output.lat.setValue(2); Text.lat.setValue("LOC"); me.armTextCheck(); } }, activateGS: func() { if (Output.vert.getValue() != 2) { Internal.flchActive = 0; Internal.altCaptureActive = 0; Output.apprArm.setBoolValue(0); Output.vert.setValue(2); Text.vert.setValue("G/S"); me.armTextCheck(); } }, checkLNAV: func(t) { if (FPLN.num.getValue() > 0 and FPLN.active.getBoolValue() and Position.gearAglFt.getValue() >= Setting.latAglFt.getValue()) { me.activateLNAV(); } else if (FPLN.active.getBoolValue() and Output.lat.getValue() != 1 and t != 1) { Output.lnavArm.setBoolValue(1); me.armTextCheck(); } }, checkFLCH: func(a) { if (Position.gearAglFt.getValue() >= a and a != 0) { me.setVertMode(4); } }, checkLOC: func(t, a) { Radio.radioSel = Input.useNav2Radio.getBoolValue(); if (Radio.inRange[Radio.radioSel].getBoolValue()) { # # Only evaulate the rest of the condition unless we are in range Radio.locDeflTemp = Radio.locDefl[Radio.radioSel].getValue(); Radio.signalQualityTemp = Radio.signalQuality[Radio.radioSel].getValue(); if (abs(Radio.locDeflTemp) <= 0.95 and Radio.locDeflTemp != 0 and Radio.signalQualityTemp >= 0.99) { me.activateLOC(); } else if (t != 1) { # Do not do this if loop calls it if (Output.lat.getValue() != 2) { Output.lnavArm.setBoolValue(0); Output.locArm.setBoolValue(1); if (a != 1) { # Don't call this if arming with G/S me.armTextCheck(); } } } } else { # Prevent bad behavior due to FG not updating it when not in range Radio.signalQuality[Radio.radioSel].setValue(0); } }, checkAPPR: func(t) { Radio.radioSel = Input.useNav2Radio.getBoolValue(); if (Radio.inRange[Radio.radioSel].getBoolValue()) { # # Only evaulate the rest of the condition unless we are in range Radio.gsDeflTemp = Radio.gsDefl[Radio.radioSel].getValue(); if (abs(Radio.gsDeflTemp) <= 0.2 and Radio.gsDeflTemp != 0 and Output.lat.getValue() == 2) { # Only capture if LOC is active me.activateGS(); } else if (t != 1) { # Do not do this if loop calls it if (Output.vert.getValue() != 2) { Output.apprArm.setBoolValue(1); } me.armTextCheck(); } } else { # Prevent bad behavior due to FG not updating it when not in range Radio.signalQuality[Radio.radioSel].setValue(0); } }, checkRadioRevision: func(l, v) { # Revert mode if signal lost Radio.radioSel = Input.useNav2Radio.getBoolValue(); Radio.inRangeTemp = Radio.inRange[Radio.radioSel].getBoolValue(); if (!Radio.inRangeTemp) { if (l == 4 or v == 6) { me.ap1Master(0); me.ap2Master(0); me.setLatMode(3); me.setVertMode(1); } else { me.setLatMode(3); # Also cancels G/S if active } } }, setClimbRateLim: func() { Internal.vsTemp = Internal.vs.getValue(); if (Internal.alt.getValue() >= Position.indicatedAltitudeFt.getValue()) { Internal.maxVs.setValue(math.round(Internal.vsTemp)); Internal.minVs.setValue(-500); } else { Internal.maxVs.setValue(500); Internal.minVs.setValue(math.round(Internal.vsTemp)); } }, resetClimbRateLim: func() { Internal.minVs.setValue(-500); Internal.maxVs.setValue(500); }, takeoffGoAround: func() { Output.vertTemp = Output.vert.getValue(); if ((Output.vertTemp == 2 or Output.vertTemp == 6) and Velocities.indicatedAirspeedKt.getValue() >= 80) { me.setLatMode(3); me.setVertMode(7); # Must be before kicking AP off Text.vert.setValue("G/A CLB"); Input.ktsMach.setBoolValue(0); me.syncKtsGa(); if (Gear.wow1.getBoolValue() or Gear.wow2.getBoolValue()) { me.ap1Master(0); me.ap2Master(0); } } else if (Gear.wow1Temp or Gear.wow2Temp) { me.athrMaster(1); if (Output.lat.getValue() != 5) { # Don't accidently disarm LNAV me.setLatMode(5); } me.setVertMode(7); Text.vert.setValue("T/O CLB"); } }, armTextCheck: func() { if (Output.apprArm.getBoolValue()) { Text.arm.setValue("ILS"); } else if (Output.locArm.getBoolValue()) { Text.arm.setValue("LOC"); } else if (Output.lnavArm.getBoolValue()) { Text.arm.setValue("LNV"); } else { Text.arm.setValue(" "); } }, syncKts: func() { Input.kts.setValue(math.clamp(math.round(Velocities.indicatedAirspeedKt.getValue()), 100, 350)); }, syncKtsGa: func() { # Same as syncKts, except doesn't go below TogaSpd Input.kts.setValue(math.clamp(math.round(Velocities.indicatedAirspeedKt.getValue()), Setting.togaSpd.getValue(), 350)); }, syncMach: func() { Input.mach.setValue(math.clamp(math.round(Velocities.indicatedMach.getValue(), 0.001), 0.5, 0.9)); }, syncHdg: func() { Input.hdg.setValue(math.round(Internal.hdgPredicted.getValue())); # Switches to track automatically }, syncAlt: func() { Input.alt.setValue(math.clamp(math.round(Internal.altPredicted.getValue(), 100), 0, 50000)); Internal.alt.setValue(math.clamp(math.round(Internal.altPredicted.getValue(), 100), 0, 50000)); }, syncVs: func() { Input.vs.setValue(math.clamp(math.round(Internal.vs.getValue(), 100), -6000, 6000)); }, syncFpa: func() { Input.fpa.setValue(math.clamp(math.round(Internal.fpa.getValue(), 0.1), -9.9, 9.9)); }, }; setlistener("/it-autoflight/input/ap1", func { Input.ap1Temp = Input.ap1.getBoolValue(); if (Input.ap1Temp != Output.ap1.getBoolValue()) { ITAF.ap1Master(Input.ap1Temp); } }); setlistener("/it-autoflight/input/ap2", func { Input.ap2Temp = Input.ap2.getBoolValue(); if (Input.ap2Temp != Output.ap2.getBoolValue()) { ITAF.ap2Master(Input.ap2Temp); } }); setlistener("/it-autoflight/input/athr", func { Input.athrTemp = Input.athr.getBoolValue(); if (Input.athrTemp != Output.athr.getBoolValue()) { ITAF.athrMaster(Input.athrTemp); } }); setlistener("/it-autoflight/input/fd1", func { Input.fd1Temp = Input.fd1.getBoolValue(); if (Input.fd1Temp != Output.fd1.getBoolValue()) { ITAF.fd1Master(Input.fd1Temp); } }); setlistener("/it-autoflight/input/fd2", func { Input.fd2Temp = Input.fd2.getBoolValue(); if (Input.fd2Temp != Output.fd2.getBoolValue()) { ITAF.fd2Master(Input.fd2Temp); } }); setlistener("/it-autoflight/input/kts-mach", func { if (Input.ktsMach.getBoolValue()) { ITAF.syncMach(); } else { ITAF.syncKts(); } }, 0, 0); setlistener("/it-autoflight/input/toga", func { if (Input.toga.getBoolValue()) { ITAF.takeoffGoAround(); Input.toga.setBoolValue(0); } }); setlistener("/it-autoflight/input/lat", func { Input.latTemp = Input.lat.getValue(); if (!Gear.wow1.getBoolValue() and !Gear.wow2.getBoolValue()) { ITAF.setLatMode(Input.latTemp); } else { ITAF.setLatArm(Input.latTemp); } }); setlistener("/it-autoflight/input/vert", func { if (!Gear.wow1.getBoolValue() and !Gear.wow2.getBoolValue()) { ITAF.setVertMode(Input.vert.getValue()); } }); setlistener("/it-autoflight/input/trk", func { Input.trkTemp = Input.trk.getBoolValue(); if (Input.trkTemp) { Input.hdgCalc = Input.hdg.getValue() + math.round(Internal.driftAngle.getValue()); if (Input.hdgCalc > 360) { # It's rounded, so this is ok. Otherwise do >= 360.5 Input.hdgCalc = Input.hdgCalc - 360; } else if (Input.hdgCalc < 1) { # It's rounded, so this is ok. Otherwise do < 0.5 Input.hdgCalc = Input.hdgCalc + 360; } Input.hdg.setValue(Input.hdgCalc); Custom.hdgSel.setValue(Input.hdgCalc); } else { Input.hdgCalc = Input.hdg.getValue() - math.round(Internal.driftAngle.getValue()); if (Input.hdgCalc > 360) { # It's rounded, so this is ok. Otherwise do >= 360.5 Input.hdgCalc = Input.hdgCalc - 360; } else if (Input.hdgCalc < 1) { # It's rounded, so this is ok. Otherwise do < 0.5 Input.hdgCalc = Input.hdgCalc + 360; } Input.hdg.setValue(Input.hdgCalc); Custom.hdgSel.setValue(Input.hdgCalc); } Misc.efis0Trk.setBoolValue(Input.trkTemp); # For Canvas Nav Display. Misc.efis1Trk.setBoolValue(Input.trkTemp); # For Canvas Nav Display. }, 0, 0); setlistener("/sim/signals/fdm-initialized", func { ITAF.init(); }); # For Canvas Nav Display. setlistener("/it-autoflight/input/hdg", func { setprop("/autopilot/settings/heading-bug-deg", getprop("/it-autoflight/input/hdg")); }); setlistener("/it-autoflight/internal/alt", func { setprop("/autopilot/settings/target-altitude-ft", getprop("/it-autoflight/internal/alt")); }); var loopTimer = maketimer(0.1, ITAF, ITAF.loop); var slowLoopTimer = maketimer(1, ITAF, ITAF.slowLoop);