#include "Math.hpp" #include "Surface.hpp" #include "Wing.hpp" namespace yasim { Wing::Wing() { _mirror = false; _base[0] = _base[1] = _base[2] = 0; _length = 0; _chord = 0; _taper = 0; _sweep = 0; _dihedral = 0; _stall = 0; _stallWidth = 0; _stallPeak = 0; _twist = 0; _camber = 0; _incidence = 0; _inducedDrag = 1; _dragScale = 1; _liftRatio = 1; _flap0Start = 0; _flap0End = 0; _flap0Lift = 0; _flap0Drag = 0; _flap1Start = 0; _flap1End = 0; _flap1Lift = 0; _flap1Drag = 0; _spoilerStart = 0; _spoilerEnd = 0; _spoilerLift = 0; _spoilerDrag = 0; _slatStart = 0; _slatEnd = 0; _slatAoA = 0; _slatDrag = 0; } Wing::~Wing() { int i; for(i=0; i<_surfs.size(); i++) { SurfRec* s = (SurfRec*)_surfs.get(i); delete s->surface; delete s; } } int Wing::numSurfaces() { return _surfs.size(); } Surface* Wing::getSurface(int n) { return ((SurfRec*)_surfs.get(n))->surface; } float Wing::getSurfaceWeight(int n) { return ((SurfRec*)_surfs.get(n))->weight; } void Wing::setMirror(bool mirror) { _mirror = mirror; } void Wing::setBase(float* base) { int i; for(i=0; i<3; i++) _base[i] = base[i]; } void Wing::setLength(float length) { _length = length; } void Wing::setChord(float chord) { _chord = chord; } void Wing::setTaper(float taper) { _taper = taper; } void Wing::setSweep(float sweep) { _sweep = sweep; } void Wing::setDihedral(float dihedral) { _dihedral = dihedral; } void Wing::setStall(float aoa) { _stall = aoa; } void Wing::setStallWidth(float angle) { _stallWidth = angle; } void Wing::setStallPeak(float fraction) { _stallPeak = fraction; } void Wing::setTwist(float angle) { _twist = angle; } void Wing::setCamber(float camber) { _camber = camber; } void Wing::setIncidence(float incidence) { _incidence = incidence; int i; for(i=0; i<_surfs.size(); i++) ((SurfRec*)_surfs.get(i))->surface->setIncidence(incidence); } void Wing::setFlap0(float start, float end, float lift, float drag) { _flap0Start = start; _flap0End = end; _flap0Lift = lift; _flap0Drag = drag; } void Wing::setFlap1(float start, float end, float lift, float drag) { _flap1Start = start; _flap1End = end; _flap1Lift = lift; _flap1Drag = drag; } void Wing::setSlat(float start, float end, float aoa, float drag) { _slatStart = start; _slatEnd = end; _slatAoA = aoa; _slatDrag = drag; } void Wing::setSpoiler(float start, float end, float lift, float drag) { _spoilerStart = start; _spoilerEnd = end; _spoilerLift = lift; _spoilerDrag = drag; } void Wing::setFlap0(float lval, float rval) { lval = Math::clamp(lval, -1, 1); rval = Math::clamp(rval, -1, 1); int i; for(i=0; i<_flap0Surfs.size(); i++) { ((Surface*)_flap0Surfs.get(i))->setFlap(lval); if(_mirror) ((Surface*)_flap0Surfs.get(++i))->setFlap(rval); } } void Wing::setFlap1(float lval, float rval) { lval = Math::clamp(lval, -1, 1); rval = Math::clamp(rval, -1, 1); int i; for(i=0; i<_flap1Surfs.size(); i++) { ((Surface*)_flap1Surfs.get(i))->setFlap(lval); if(_mirror) ((Surface*)_flap1Surfs.get(++i))->setFlap(rval); } } void Wing::setSpoiler(float lval, float rval) { lval = Math::clamp(lval, 0, 1); rval = Math::clamp(rval, 0, 1); int i; for(i=0; i<_spoilerSurfs.size(); i++) { ((Surface*)_spoilerSurfs.get(i))->setSpoiler(lval); if(_mirror) ((Surface*)_spoilerSurfs.get(++i))->setSpoiler(rval); } } void Wing::setSlat(float val) { val = Math::clamp(val, 0, 1); int i; for(i=0; i<_slatSurfs.size(); i++) ((Surface*)_slatSurfs.get(i))->setSlat(val); } float Wing::getGroundEffect(float* posOut) { int i; for(i=0; i<3; i++) posOut[i] = _base[i]; float span = _length * Math::cos(_sweep) * Math::cos(_dihedral); span = 2*(span + Math::abs(_base[2])); return span; } void Wing::getTip(float* tip) { tip[0] = -Math::tan(_sweep); tip[1] = Math::cos(_dihedral); tip[2] = Math::sin(_dihedral); Math::unit3(tip, tip); Math::mul3(_length, tip, tip); Math::add3(_base, tip, tip); } bool Wing::isMirrored() { return _mirror; } void Wing::compile() { // Have we already been compiled? if(_surfs.size() != 0) return; // Assemble the start/end coordinates into an array, sort them, // and remove duplicates. This gives us the boundaries of our // segments. float bounds[8]; bounds[0] = _flap0Start; bounds[1] = _flap0End; bounds[2] = _flap1Start; bounds[3] = _flap1End; bounds[4] = _spoilerStart; bounds[5] = _spoilerEnd; bounds[6] = _slatStart; bounds[7] = _slatEnd; // Sort in increasing order int i; for(i=0; i<8; i++) { int minIdx = i; float minVal = bounds[i]; int j; for(j=i+1; j<8; j++) { if(bounds[j] < minVal) { minIdx = j; minVal = bounds[j]; } } float tmp = bounds[i]; bounds[i] = minVal; bounds[minIdx] = tmp; } // Uniqify float last = bounds[0]; int nbounds = 1; for(i=1; i<8; i++) { if(bounds[i] != last) bounds[nbounds++] = bounds[i]; last = bounds[i]; } // Calculate a "nominal" segment length equal to an average chord, // normalized to lie within 0-1 over the length of the wing. float segLen = _chord * (0.5f*(_taper+1)) / _length; // Generating a unit vector pointing out the left wing. float left[3]; left[0] = -Math::tan(_sweep); left[1] = Math::cos(_dihedral); left[2] = Math::sin(_dihedral); Math::unit3(left, left); // Calculate coordinates for the root and tip of the wing float root[3], tip[3]; Math::set3(_base, root); Math::set3(left, tip); Math::mul3(_length, tip, tip); Math::add3(root, tip, tip); // The wing's Y axis will be the "left" vector. The Z axis will // be perpendicular to this and the local (!) X axis, because we // want motion along the local X axis to be zero AoA (i.e. in the // wing's XY plane) by definition. Then the local X coordinate is // just Y cross Z. float orient[9], rightOrient[9]; float *x = orient, *y = orient+3, *z = orient+6; x[0] = 1; x[1] = 0; x[2] = 0; Math::set3(left, y); Math::cross3(x, y, z); Math::unit3(z, z); Math::cross3(y, z, x); if(_mirror) { // Derive the right side orientation matrix from this one. int i; for(i=0; i<9; i++) rightOrient[i] = orient[i]; // Negate all Y coordinates, this gets us a valid basis, but // it's left handed! So... for(i=1; i<9; i+=3) rightOrient[i] = -rightOrient[i]; // Change the direction of the Y axis to get back to a // right-handed system. for(i=3; i<6; i++) rightOrient[i] = -rightOrient[i]; } // Now go through each boundary and make segments for(i=0; i<(nbounds-1); i++) { float start = bounds[i]; float end = bounds[i+1]; float mid = (start+end)/2; bool flap0=0, flap1=0, slat=0, spoiler=0; if(_flap0Start < mid && mid < _flap0End) flap0 = 1; if(_flap1Start < mid && mid < _flap1End) flap1 = 1; if(_slatStart < mid && mid < _slatEnd) slat = 1; if(_spoilerStart < mid && mid < _spoilerEnd) spoiler = 1; // FIXME: Should probably detect an error here if both flap0 // and flap1 are set. Right now flap1 overrides. int nSegs = (int)Math::ceil((end-start)/segLen); if (_twist != 0 && nSegs < 8) // more segments if twisted nSegs = 8; float segWid = _length * (end - start)/nSegs; int j; for(j=0; jsurface = s; sr->weight = chord * segWid; s->setTotalDrag(sr->weight); s->setTwist(_twist * frac); _surfs.add(sr); if(_mirror) { pos[1] = -pos[1]; s = newSurface(pos, rightOrient, chord, flap0, flap1, slat, spoiler); sr = new SurfRec(); sr->surface = s; sr->weight = chord * segWid; s->setTotalDrag(sr->weight); s->setTwist(_twist * Math::sqrt(frac)); _surfs.add(sr); } } } // Last of all, re-set the incidence in case setIncidence() was // called before we were compiled. setIncidence(_incidence); } float Wing::getDragScale() { return _dragScale; } void Wing::setDragScale(float scale) { _dragScale = scale; int i; for(i=0; i<_surfs.size(); i++) { SurfRec* s = (SurfRec*)_surfs.get(i); s->surface->setTotalDrag(scale * s->weight); } } void Wing::setLiftRatio(float ratio) { _liftRatio = ratio; int i; for(i=0; i<_surfs.size(); i++) ((SurfRec*)_surfs.get(i))->surface->setZDrag(ratio); } float Wing::getLiftRatio() { return _liftRatio; } Surface* Wing::newSurface(float* pos, float* orient, float chord, bool flap0, bool flap1, bool slat, bool spoiler) { Surface* s = new Surface(); s->setPosition(pos); s->setOrientation(orient); s->setChord(chord); // Camber is expressed as a fraction of stall peak, so convert. s->setBaseZDrag(_camber*_stallPeak); // The "main" (i.e. normal) stall angle float stallAoA = _stall - _stallWidth/4; s->setStall(0, stallAoA); s->setStallWidth(0, _stallWidth); s->setStallPeak(0, _stallPeak); // The negative AoA stall is the same if we're using an uncambered // airfoil, otherwise a "little badder". if(_camber > 0) { s->setStall(1, stallAoA * 0.8f); s->setStallWidth(1, _stallWidth * 0.5f); } else { s->setStall(1, stallAoA); s->setStall(1, _stallWidth); } // The "reverse" stalls are unmeasurable junk. Just use 13deg and // "sharp". s->setStallPeak(1, 1); int i; for(i=2; i<4; i++) { s->setStall(i, 0.2267f); s->setStallWidth(i, 1); } if(flap0) s->setFlapParams(_flap0Lift, _flap0Drag); if(flap1) s->setFlapParams(_flap1Lift, _flap1Drag); if(slat) s->setSlatParams(_slatAoA, _slatDrag); if(spoiler) s->setSpoilerParams(_spoilerLift, _spoilerDrag); if(flap0) _flap0Surfs.add(s); if(flap1) _flap1Surfs.add(s); if(slat) _slatSurfs.add(s); if(spoiler) _spoilerSurfs.add(s); s->setInducedDrag(_inducedDrag); return s; } void Wing::interp(float* v1, float* v2, float frac, float* out) { out[0] = v1[0] + frac*(v2[0]-v1[0]); out[1] = v1[1] + frac*(v2[1]-v1[1]); out[2] = v1[2] + frac*(v2[2]-v1[2]); } }; // namespace yasim