/// <returns>aTraverse</returns>
public virtual double RecalculateDelta_g(bool revert = true)
{
//return basin.gHpure * 1000;
double a;
double aTraverse;
double aVertical;
var aMeridian = EllipsoidAcceleration.Centrifugal(this, out a, out aTraverse, out aVertical);
// range: 0..0.0034
var newDeflectionAngleTan = (gHpure + aMeridian) / (gVpure /*+ aVertical*/);
//todo try to rid of newDeflectionAngle and calculate without Atan, Tan
var newDeflectionAngle = Math.Atan(newDeflectionAngleTan);
// range -0.1..0m
//return (basin.GoodDeflectionAngle - newDeflectionAngle) * basin.r;
// range: 0..0.0034
//return Triangles.TansSum(-basin.ThetaTan, newDeflectionAngle)*1000;
Delta_g_meridian = (revert && Vartheta < 0)
? Math.PI - newDeflectionAngle
: newDeflectionAngle;
// range -0.1..0.1m
//return (basin.Delta_gq - newDelta_g) * basin.r;
return(aTraverse);
}
public void Centrifugal()
{
Assert.AreEqual(90, new UnitVector3D(1, 0, 0).AngleTo(new UnitVector3D(0, 1, 0)).Degrees);
Assert.AreEqual(0, new UnitVector3D(1, 0, 0).DotProduct(new UnitVector3D(0, 1, 0)));
Assert.AreEqual(1, new UnitVector3D(1, 0, 0).DotProduct(new UnitVector3D(1, 0, 0)));
double a, aTraverse, aVertical;
Assert.AreEqual(0, EllipsoidAcceleration.Centrifugal(basin0), .01);
Assert.AreEqual(.024, EllipsoidAcceleration.Centrifugal(basin31), .01);
Assert.AreEqual(0, EllipsoidAcceleration.Centrifugal(basin95, out a, out aTraverse, out aVertical), .000001);
Assert.AreEqual(.0339, a, .0001);
Assert.AreEqual(0, aTraverse);
Assert.AreEqual(.0339, aVertical, .0001);
EllipsoidAcceleration.AxisOfRotation = new UnitVector3D(1, 0, 0);
Assert.AreEqual(-.003, EllipsoidAcceleration.Centrifugal(basin0, out a, out aTraverse, out aVertical), .001);
Assert.AreEqual(.034, a, .01);
Assert.AreEqual(-.003, aTraverse, .001);
Assert.AreEqual(.0331, aVertical, .0001);
Assert.AreEqual(-.017, EllipsoidAcceleration.Centrifugal(basin31, out a, out aTraverse, out aVertical), .001);
Assert.AreEqual(.024, a, .01);
Assert.AreEqual(.005, aTraverse, .001);
Assert.AreEqual(.0157, aVertical, .0001);
Assert.AreEqual(0, EllipsoidAcceleration.Centrifugal(basin95), .01);
}
public override double?GetAltitude(MeridianCoor basin)
{
var aH = EllipsoidAcceleration.Centrifugal(basin);
//var aV = a * Math.Sin(basin.Theta);
return(aH * 1000);
}
internal override void PreInit(HealpixManager man)
{
base.PreInit(man);
LambdaSin = Math.Sin(Lambda.Value);
LambdaMinusPi2Sin = Math.Sin(Lambda.Value - Math.PI / 2);
LambdaCos = Math.Cos(Lambda.Value);
BetaSin = Math.Sin(Beta.Value);
BetaCos = Math.Cos(Beta.Value);
/*
* var thetaTan = Ellipsoid.CalcThetaTan(Beta.Value);
* var varphi = Ellipsoid.CalcVarPhi(thetaTan);
* Theta = Math.PI / 2 - varphi; // faster than Atan(thetaTan) and Atan(thetaTan)<0 when thetaTan>Pi/2
*/
// new
Theta = Beta.Value;
var thetaTan = Math.Tan(Theta);
var varphi = Math.PI / 2 - Theta;
// end of new
InitROfEllipse(man, Ellipsoid.Radius(varphi));
Vartheta = Ellipsoid.CalcVarTheta(thetaTan);
// vertical to ellipsoid surface
var g = EllipsoidAcceleration.GravitationalSomigliana(varphi);
//return g * 100;
double a, aTraverse, aVertical;
var aMeridian = EllipsoidAcceleration.Centrifugal(this, out a, out aTraverse, out aVertical);
// vertical to ellipsoid surface
var aVert = Math.Abs(a * Math.Sin(Vartheta));
// horizontal to ellipsoid surface
//var aHoriz = a * Math.Cos(Vartheta);
// vertical to sphere
gVpure = (g + aVert) * Math.Cos(GoodDeflectionAngle); //Triangles.CalcGPureToCenter
//return gVpure*10000;
// horizontal to sphere
// max: .03299
// horizontal to sphere
var gHor = (g + aVert) * Math.Sin(GoodDeflectionAngle);
//gToCenterByThetaCos = gVpure / Math.Abs(Math.Cos(Theta));
//return basin.GoodDeflectionAngle * 1000;
// vertical to sphere
var aV = a * Math.Sin(Theta);
//return aV * 100;*/
//return aH * 100;
gHpure = gHor - aMeridian;
Delta_g_meridian = GoodDeflectionAngle;
}
public void Centrifugal_Y()
{
double a, aTraverse, aVertical;
EllipsoidAcceleration.AxisOfRotation = new UnitVector3D(0, 1, 0);
Assert.AreEqual(-.003, EllipsoidAcceleration.Centrifugal(basin0, out a, out aTraverse, out aVertical), .001);
Assert.AreEqual(.034, a, .01);
Assert.AreEqual(.003, aTraverse, .001);
Assert.AreEqual(.0331, aVertical, .0001);
Assert.AreEqual(-.002, EllipsoidAcceleration.Centrifugal(basin7, out a, out aTraverse, out aVertical), .001);
Assert.AreEqual(.024, a, .01);
Assert.AreEqual(-.005, aTraverse, .001);
Assert.AreEqual(.0331, aVertical, .0001);
}
public void Centrifugal_aMeridian_BugOfCone()
{
double a, aTraverse, aVertical;
EllipsoidAcceleration.AxisOfRotation = new UnitVector3D(1, 0, 0);
Assert.AreEqual(-.003, EllipsoidAcceleration.Centrifugal(basin77, out a, out aTraverse, out aVertical), .001);
Assert.AreEqual(.017, a, .01);
Assert.AreEqual(.017, aTraverse, .001);
Assert.AreEqual(.0174, aVertical, .0001);
EllipsoidAcceleration.AxisOfRotation = new UnitVector3D(0, 1, 0);
Assert.AreEqual(-.003, EllipsoidAcceleration.Centrifugal(basin77, out a, out aTraverse, out aVertical), .001);
Assert.AreEqual(.017, a, .01);
Assert.AreEqual(-.017, aTraverse, .001);
Assert.AreEqual(.0174, aVertical, .0001);
Assert.AreEqual(-.001, EllipsoidAcceleration.Centrifugal(basin31, out a, out aTraverse, out aVertical), .001);
Assert.AreEqual(.024, a, .01);
Assert.AreEqual(-.005, aTraverse, .001);
Assert.AreEqual(.0331, aVertical, .0001);
}