public double execute(double in) throws DMLRuntimeException {
switch (bFunc) {
case SIN:
return FASTMATH ? FastMath.sin(in) : Math.sin(in);
case COS:
return FASTMATH ? FastMath.cos(in) : Math.cos(in);
case TAN:
return FASTMATH ? FastMath.tan(in) : Math.tan(in);
case ASIN:
return FASTMATH ? FastMath.asin(in) : Math.asin(in);
case ACOS:
return FASTMATH ? FastMath.acos(in) : Math.acos(in);
case ATAN:
return Math.atan(in); // faster in Math
case CEIL:
return FASTMATH ? FastMath.ceil(in) : Math.ceil(in);
case FLOOR:
return FASTMATH ? FastMath.floor(in) : Math.floor(in);
case LOG:
return FASTMATH ? FastMath.log(in) : Math.log(in);
case LOG_NZ:
return (in == 0) ? 0 : FASTMATH ? FastMath.log(in) : Math.log(in);
case ABS:
return Math.abs(in); // no need for FastMath
case SIGN:
return FASTMATH ? FastMath.signum(in) : Math.signum(in);
case SQRT:
return Math.sqrt(in); // faster in Math
case EXP:
return FASTMATH ? FastMath.exp(in) : Math.exp(in);
case ROUND:
return Math.round(in); // no need for FastMath
case PLOGP:
if (in == 0.0) return 0.0;
else if (in < 0) return Double.NaN;
else return (in * (FASTMATH ? FastMath.log(in) : Math.log(in)));
case SPROP:
// sample proportion: P*(1-P)
return in * (1 - in);
case SIGMOID:
// sigmoid: 1/(1+exp(-x))
return FASTMATH ? 1 / (1 + FastMath.exp(-in)) : 1 / (1 + Math.exp(-in));
case SELP:
// select positive: x*(x>0)
return (in > 0) ? in : 0;
default:
throw new DMLRuntimeException("Builtin.execute(): Unknown operation: " + bFunc);
}
}
/**
* {@inheritDoc}
*
* <p>Returns {@code Double.NEGATIVE_INFINITY} when {@code p == 0} and {@code
* Double.POSITIVE_INFINITY} when {@code p == 1}.
*/
@Override
public double inverseCumulativeProbability(double p) throws OutOfRangeException {
double ret;
if (p < 0 || p > 1) {
throw new OutOfRangeException(p, 0, 1);
} else if (p == 0) {
ret = Double.NEGATIVE_INFINITY;
} else if (p == 1) {
ret = Double.POSITIVE_INFINITY;
} else {
ret = median + scale * FastMath.tan(FastMath.PI * (p - .5));
}
return ret;
}
/**
* Simple constructor.
*
* <p>The {@code applyBefore} parameter is mainly used when the differential effect is associated
* with a maneuver. In this case, the parameter must be set to {@code false}.
*
* @param orbit0 original orbit at reference date
* @param orbit1 shifted orbit at reference date
* @param applyBefore if true, effect is applied both before and after reference date, if false it
* is only applied after reference date
* @param referenceRadius reference radius of the Earth for the potential model (m)
* @param mu central attraction coefficient (m³/s²)
* @param j2 un-normalized zonal coefficient (about +1.08e-3 for Earth)
*/
public J2DifferentialEffect(
final Orbit orbit0,
final Orbit orbit1,
final boolean applyBefore,
final double referenceRadius,
final double mu,
final double j2) {
this.referenceDate = orbit0.getDate();
this.applyBefore = applyBefore;
// extract useful parameters
final double a0 = orbit0.getA();
final double e0 = orbit0.getE();
final double i0 = orbit0.getI();
final double a1 = orbit1.getA();
final double e1 = orbit1.getE();
final double i1 = orbit1.getI();
// compute reference drifts
final double oMe2 = 1 - e0 * e0;
final double ratio = referenceRadius / (a0 * oMe2);
final double cosI = FastMath.cos(i0);
final double sinI = FastMath.sin(i0);
final double n = FastMath.sqrt(mu / a0) / a0;
final double c = ratio * ratio * n * j2;
final double refPaDot = 0.75 * c * (4 - 5 * sinI * sinI);
final double refRaanDot = -1.5 * c * cosI;
// differential model on perigee argument drift
final double dPaDotDa = -3.5 * refPaDot / a0;
final double dPaDotDe = 4 * refPaDot * e0 / oMe2;
final double dPaDotDi = -7.5 * c * sinI * cosI;
dPaDot = dPaDotDa * (a1 - a0) + dPaDotDe * (e1 - e0) + dPaDotDi * (i1 - i0);
// differential model on ascending node drift
final double dRaanDotDa = -3.5 * refRaanDot / a0;
final double dRaanDotDe = 4 * refRaanDot * e0 / oMe2;
final double dRaanDotDi = -refRaanDot * FastMath.tan(i0);
dRaanDot = dRaanDotDa * (a1 - a0) + dRaanDotDe * (e1 - e0) + dRaanDotDi * (i1 - i0);
}