Package | Description |
---|---|
org.hipparchus.util |
Convenience routines and common data structures used throughout the Hipparchus library.
|
Modifier and Type | Method and Description |
---|---|
FieldTuple<T> |
FieldTuple.abs()
absolute value.
|
FieldTuple<T> |
FieldTuple.acos()
Arc cosine operation.
|
FieldTuple<T> |
FieldTuple.acosh()
Inverse hyperbolic cosine operation.
|
FieldTuple<T> |
FieldTuple.add(double a)
'+' operator.
|
FieldTuple<T> |
FieldTuple.add(FieldTuple<T> a)
Compute this + a.
|
FieldTuple<T> |
FieldTuple.asin()
Arc sine operation.
|
FieldTuple<T> |
FieldTuple.asinh()
Inverse hyperbolic sine operation.
|
FieldTuple<T> |
FieldTuple.atan()
Arc tangent operation.
|
FieldTuple<T> |
FieldTuple.atan2(FieldTuple<T> x)
Two arguments arc tangent operation.
|
FieldTuple<T> |
FieldTuple.atanh()
Inverse hyperbolic tangent operation.
|
FieldTuple<T> |
FieldTuple.cbrt()
Cubic root.
|
FieldTuple<T> |
FieldTuple.ceil()
Get the smallest whole number larger than instance.
|
FieldTuple<T> |
FieldTuple.copySign(double sign)
Returns the instance with the sign of the argument.
|
FieldTuple<T> |
FieldTuple.copySign(FieldTuple<T> sign)
Returns the instance with the sign of the argument.
|
FieldTuple<T> |
FieldTuple.cos()
Cosine operation.
|
FieldTuple<T> |
FieldTuple.cosh()
Hyperbolic cosine operation.
|
FieldTuple<T> |
FieldTuple.divide(double a)
'÷' operator.
|
FieldTuple<T> |
FieldTuple.divide(FieldTuple<T> a)
Compute this ÷ a.
|
FieldTuple<T> |
FieldTuple.exp()
Exponential.
|
FieldTuple<T> |
FieldTuple.expm1()
Exponential minus 1.
|
FieldTuple<T> |
FieldTuple.floor()
Get the largest whole number smaller than instance.
|
FieldTuple<T> |
FieldTuple.hypot(FieldTuple<T> y)
Returns the hypotenuse of a triangle with sides
this and y
- sqrt(this2 +y2)
avoiding intermediate overflow or underflow. |
FieldTuple<T> |
FieldTuple.linearCombination(double[] a,
FieldTuple<T>[] b)
Compute a linear combination.
|
FieldTuple<T> |
FieldTuple.linearCombination(double a1,
FieldTuple<T> b1,
double a2,
FieldTuple<T> b2)
Compute a linear combination.
|
FieldTuple<T> |
FieldTuple.linearCombination(double a1,
FieldTuple<T> b1,
double a2,
FieldTuple<T> b2,
double a3,
FieldTuple<T> b3)
Compute a linear combination.
|
FieldTuple<T> |
FieldTuple.linearCombination(double a1,
FieldTuple<T> b1,
double a2,
FieldTuple<T> b2,
double a3,
FieldTuple<T> b3,
double a4,
FieldTuple<T> b4)
Compute a linear combination.
|
FieldTuple<T> |
FieldTuple.linearCombination(FieldTuple<T>[] a,
FieldTuple<T>[] b)
Compute a linear combination.
|
FieldTuple<T> |
FieldTuple.linearCombination(FieldTuple<T> a1,
FieldTuple<T> b1,
FieldTuple<T> a2,
FieldTuple<T> b2)
Compute a linear combination.
|
FieldTuple<T> |
FieldTuple.linearCombination(FieldTuple<T> a1,
FieldTuple<T> b1,
FieldTuple<T> a2,
FieldTuple<T> b2,
FieldTuple<T> a3,
FieldTuple<T> b3)
Compute a linear combination.
|
FieldTuple<T> |
FieldTuple.linearCombination(FieldTuple<T> a1,
FieldTuple<T> b1,
FieldTuple<T> a2,
FieldTuple<T> b2,
FieldTuple<T> a3,
FieldTuple<T> b3,
FieldTuple<T> a4,
FieldTuple<T> b4)
Compute a linear combination.
|
FieldTuple<T> |
FieldTuple.log()
Natural logarithm.
|
FieldTuple<T> |
FieldTuple.log10()
Base 10 logarithm.
|
FieldTuple<T> |
FieldTuple.log1p()
Shifted natural logarithm.
|
FieldTuple<T> |
FieldTuple.multiply(double a)
'×' operator.
|
FieldTuple<T> |
FieldTuple.multiply(FieldTuple<T> a)
Compute this × a.
|
FieldTuple<T> |
FieldTuple.multiply(int n)
Compute n × this.
|
FieldTuple<T> |
FieldTuple.negate()
Returns the additive inverse of
this element. |
FieldTuple<T> |
FieldTuple.pow(double p)
Power operation.
|
FieldTuple<T> |
FieldTuple.pow(FieldTuple<T> e)
Power operation.
|
FieldTuple<T> |
FieldTuple.pow(int n)
Integer power operation.
|
FieldTuple<T> |
FieldTuple.reciprocal()
Returns the multiplicative inverse of
this element. |
FieldTuple<T> |
FieldTuple.remainder(double a)
IEEE remainder operator.
|
FieldTuple<T> |
FieldTuple.remainder(FieldTuple<T> a)
IEEE remainder operator.
|
FieldTuple<T> |
FieldTuple.rint()
Get the whole number that is the nearest to the instance, or the even one if x is exactly half way between two integers.
|
FieldTuple<T> |
FieldTuple.rootN(int n)
Nth root.
|
FieldTuple<T> |
FieldTuple.scalb(int n)
Multiply the instance by a power of 2.
|
FieldTuple<T> |
FieldTuple.signum()
Compute the signum of the instance.
|
FieldTuple<T> |
FieldTuple.sin()
Sine operation.
|
FieldTuple<T> |
FieldTuple.sinh()
Hyperbolic sine operation.
|
FieldTuple<T> |
FieldTuple.sqrt()
Square root.
|
FieldTuple<T> |
FieldTuple.subtract(double a)
'-' operator.
|
FieldTuple<T> |
FieldTuple.subtract(FieldTuple<T> a)
Compute this - a.
|
FieldTuple<T> |
FieldTuple.tan()
Tangent operation.
|
FieldTuple<T> |
FieldTuple.tanh()
Hyperbolic tangent operation.
|
Modifier and Type | Method and Description |
---|---|
Field<FieldTuple<T>> |
FieldTuple.getField()
Get the
Field to which the instance belongs. |
Modifier and Type | Method and Description |
---|---|
FieldTuple<T> |
FieldTuple.add(FieldTuple<T> a)
Compute this + a.
|
FieldTuple<T> |
FieldTuple.atan2(FieldTuple<T> x)
Two arguments arc tangent operation.
|
FieldTuple<T> |
FieldTuple.copySign(FieldTuple<T> sign)
Returns the instance with the sign of the argument.
|
FieldTuple<T> |
FieldTuple.divide(FieldTuple<T> a)
Compute this ÷ a.
|
FieldTuple<T> |
FieldTuple.hypot(FieldTuple<T> y)
Returns the hypotenuse of a triangle with sides
this and y
- sqrt(this2 +y2)
avoiding intermediate overflow or underflow. |
FieldTuple<T> |
FieldTuple.linearCombination(double[] a,
FieldTuple<T>[] b)
Compute a linear combination.
|
FieldTuple<T> |
FieldTuple.linearCombination(double a1,
FieldTuple<T> b1,
double a2,
FieldTuple<T> b2)
Compute a linear combination.
|
FieldTuple<T> |
FieldTuple.linearCombination(double a1,
FieldTuple<T> b1,
double a2,
FieldTuple<T> b2)
Compute a linear combination.
|
FieldTuple<T> |
FieldTuple.linearCombination(double a1,
FieldTuple<T> b1,
double a2,
FieldTuple<T> b2,
double a3,
FieldTuple<T> b3)
Compute a linear combination.
|
FieldTuple<T> |
FieldTuple.linearCombination(double a1,
FieldTuple<T> b1,
double a2,
FieldTuple<T> b2,
double a3,
FieldTuple<T> b3)
Compute a linear combination.
|
FieldTuple<T> |
FieldTuple.linearCombination(double a1,
FieldTuple<T> b1,
double a2,
FieldTuple<T> b2,
double a3,
FieldTuple<T> b3)
Compute a linear combination.
|
FieldTuple<T> |
FieldTuple.linearCombination(double a1,
FieldTuple<T> b1,
double a2,
FieldTuple<T> b2,
double a3,
FieldTuple<T> b3,
double a4,
FieldTuple<T> b4)
Compute a linear combination.
|
FieldTuple<T> |
FieldTuple.linearCombination(double a1,
FieldTuple<T> b1,
double a2,
FieldTuple<T> b2,
double a3,
FieldTuple<T> b3,
double a4,
FieldTuple<T> b4)
Compute a linear combination.
|
FieldTuple<T> |
FieldTuple.linearCombination(double a1,
FieldTuple<T> b1,
double a2,
FieldTuple<T> b2,
double a3,
FieldTuple<T> b3,
double a4,
FieldTuple<T> b4)
Compute a linear combination.
|
FieldTuple<T> |
FieldTuple.linearCombination(double a1,
FieldTuple<T> b1,
double a2,
FieldTuple<T> b2,
double a3,
FieldTuple<T> b3,
double a4,
FieldTuple<T> b4)
Compute a linear combination.
|
FieldTuple<T> |
FieldTuple.linearCombination(FieldTuple<T>[] a,
FieldTuple<T>[] b)
Compute a linear combination.
|
FieldTuple<T> |
FieldTuple.linearCombination(FieldTuple<T>[] a,
FieldTuple<T>[] b)
Compute a linear combination.
|
FieldTuple<T> |
FieldTuple.linearCombination(FieldTuple<T> a1,
FieldTuple<T> b1,
FieldTuple<T> a2,
FieldTuple<T> b2)
Compute a linear combination.
|
FieldTuple<T> |
FieldTuple.linearCombination(FieldTuple<T> a1,
FieldTuple<T> b1,
FieldTuple<T> a2,
FieldTuple<T> b2)
Compute a linear combination.
|
FieldTuple<T> |
FieldTuple.linearCombination(FieldTuple<T> a1,
FieldTuple<T> b1,
FieldTuple<T> a2,
FieldTuple<T> b2)
Compute a linear combination.
|
FieldTuple<T> |
FieldTuple.linearCombination(FieldTuple<T> a1,
FieldTuple<T> b1,
FieldTuple<T> a2,
FieldTuple<T> b2)
Compute a linear combination.
|
FieldTuple<T> |
FieldTuple.linearCombination(FieldTuple<T> a1,
FieldTuple<T> b1,
FieldTuple<T> a2,
FieldTuple<T> b2,
FieldTuple<T> a3,
FieldTuple<T> b3)
Compute a linear combination.
|
FieldTuple<T> |
FieldTuple.linearCombination(FieldTuple<T> a1,
FieldTuple<T> b1,
FieldTuple<T> a2,
FieldTuple<T> b2,
FieldTuple<T> a3,
FieldTuple<T> b3)
Compute a linear combination.
|
FieldTuple<T> |
FieldTuple.linearCombination(FieldTuple<T> a1,
FieldTuple<T> b1,
FieldTuple<T> a2,
FieldTuple<T> b2,
FieldTuple<T> a3,
FieldTuple<T> b3)
Compute a linear combination.
|
FieldTuple<T> |
FieldTuple.linearCombination(FieldTuple<T> a1,
FieldTuple<T> b1,
FieldTuple<T> a2,
FieldTuple<T> b2,
FieldTuple<T> a3,
FieldTuple<T> b3)
Compute a linear combination.
|
FieldTuple<T> |
FieldTuple.linearCombination(FieldTuple<T> a1,
FieldTuple<T> b1,
FieldTuple<T> a2,
FieldTuple<T> b2,
FieldTuple<T> a3,
FieldTuple<T> b3)
Compute a linear combination.
|
FieldTuple<T> |
FieldTuple.linearCombination(FieldTuple<T> a1,
FieldTuple<T> b1,
FieldTuple<T> a2,
FieldTuple<T> b2,
FieldTuple<T> a3,
FieldTuple<T> b3)
Compute a linear combination.
|
FieldTuple<T> |
FieldTuple.linearCombination(FieldTuple<T> a1,
FieldTuple<T> b1,
FieldTuple<T> a2,
FieldTuple<T> b2,
FieldTuple<T> a3,
FieldTuple<T> b3,
FieldTuple<T> a4,
FieldTuple<T> b4)
Compute a linear combination.
|
FieldTuple<T> |
FieldTuple.linearCombination(FieldTuple<T> a1,
FieldTuple<T> b1,
FieldTuple<T> a2,
FieldTuple<T> b2,
FieldTuple<T> a3,
FieldTuple<T> b3,
FieldTuple<T> a4,
FieldTuple<T> b4)
Compute a linear combination.
|
FieldTuple<T> |
FieldTuple.linearCombination(FieldTuple<T> a1,
FieldTuple<T> b1,
FieldTuple<T> a2,
FieldTuple<T> b2,
FieldTuple<T> a3,
FieldTuple<T> b3,
FieldTuple<T> a4,
FieldTuple<T> b4)
Compute a linear combination.
|
FieldTuple<T> |
FieldTuple.linearCombination(FieldTuple<T> a1,
FieldTuple<T> b1,
FieldTuple<T> a2,
FieldTuple<T> b2,
FieldTuple<T> a3,
FieldTuple<T> b3,
FieldTuple<T> a4,
FieldTuple<T> b4)
Compute a linear combination.
|
FieldTuple<T> |
FieldTuple.linearCombination(FieldTuple<T> a1,
FieldTuple<T> b1,
FieldTuple<T> a2,
FieldTuple<T> b2,
FieldTuple<T> a3,
FieldTuple<T> b3,
FieldTuple<T> a4,
FieldTuple<T> b4)
Compute a linear combination.
|
FieldTuple<T> |
FieldTuple.linearCombination(FieldTuple<T> a1,
FieldTuple<T> b1,
FieldTuple<T> a2,
FieldTuple<T> b2,
FieldTuple<T> a3,
FieldTuple<T> b3,
FieldTuple<T> a4,
FieldTuple<T> b4)
Compute a linear combination.
|
FieldTuple<T> |
FieldTuple.linearCombination(FieldTuple<T> a1,
FieldTuple<T> b1,
FieldTuple<T> a2,
FieldTuple<T> b2,
FieldTuple<T> a3,
FieldTuple<T> b3,
FieldTuple<T> a4,
FieldTuple<T> b4)
Compute a linear combination.
|
FieldTuple<T> |
FieldTuple.linearCombination(FieldTuple<T> a1,
FieldTuple<T> b1,
FieldTuple<T> a2,
FieldTuple<T> b2,
FieldTuple<T> a3,
FieldTuple<T> b3,
FieldTuple<T> a4,
FieldTuple<T> b4)
Compute a linear combination.
|
FieldTuple<T> |
FieldTuple.multiply(FieldTuple<T> a)
Compute this × a.
|
FieldTuple<T> |
FieldTuple.pow(FieldTuple<T> e)
Power operation.
|
FieldTuple<T> |
FieldTuple.remainder(FieldTuple<T> a)
IEEE remainder operator.
|
FieldTuple<T> |
FieldTuple.subtract(FieldTuple<T> a)
Compute this - a.
|
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