Uses of Class
org.djunits.value.vfloat.scalar.FloatAcceleration

Packages that use FloatAcceleration

Package	Description
org.djunits.value.vfloat.scalar	Float Scalar storage and calculations with units, absolute/relative.
org.djunits.value.vfloat.vector	Float Vector storage and calculations with units, absolute/relative, sparse/dense.

Uses of FloatAcceleration in org.djunits.value.vfloat.scalar

Methods in org.djunits.value.vfloat.scalar that return FloatAcceleration

Modifier and Type	Method and Description
FloatAcceleration	FloatAcceleration.abs() Set the value(s) to their absolute value.
FloatAcceleration	FloatAcceleration.acos() Set the value(s) to the arc cosine of the value(s); the resulting angle is in the range 0.0 through pi.
FloatAcceleration	FloatAcceleration.asin() Set the value(s) to the arc sine of the value(s); the resulting angle is in the range -pi/2 through pi/2.
FloatAcceleration	FloatAcceleration.atan() Set the value(s) to the arc tangent of the value(s); the resulting angle is in the range -pi/2 through pi/2.
FloatAcceleration	FloatAcceleration.cbrt() Set the value(s) to the(ir) cube root.
FloatAcceleration	FloatAcceleration.ceil() Set the value(s) to the smallest (closest to negative infinity) value(s) that are greater than or equal to the argument and equal to a mathematical integer.
FloatAcceleration	FloatAcceleration.cos() Set the value(s) to the trigonometric cosine of the value(s).
FloatAcceleration	FloatAcceleration.cosh() Set the value(s) to the hyperbolic cosine of the value(s).
FloatAcceleration	FloatAcceleration.divideBy(double factor) Divide scalar by a double factor.
FloatAcceleration	FloatAcceleration.divideBy(float divisor) Scale the value(s) by the inverse of a factor; i.e.
FloatAcceleration	FloatForce.divideBy(FloatMass v) Calculate the division of FloatForce and FloatMass, which results in a FloatAcceleration scalar.
FloatAcceleration	FloatSpeed.divideBy(FloatTime.Rel v) Calculate the division of FloatSpeed and FloatTime, which results in a FloatAcceleration scalar.
FloatAcceleration	FloatAcceleration.exp() Set the value(s) to Euler's number e raised to the power of the value(s).
FloatAcceleration	FloatAcceleration.expm1() Set the value(s) to Euler's number e raised to the power of the value(s) minus 1 (e^x - 1).
FloatAcceleration	FloatAcceleration.floor() Set the value(s) to the largest (closest to positive infinity) value(s) that are less than or equal to the argument and equal to a mathematical integer.
static FloatAcceleration	FloatAcceleration.interpolate(FloatAcceleration zero, FloatAcceleration one, double ratio) Interpolate between two values.
static FloatAcceleration	FloatAcceleration.interpolate(FloatAcceleration zero, FloatAcceleration one, float ratio) Interpolate between two values.
FloatAcceleration	FloatAcceleration.inv() Set the value(s) to the complement (1.0/x) of the value(s).
FloatAcceleration	FloatAcceleration.log() Set the value(s) to the natural logarithm (base e) of the value(s).
FloatAcceleration	FloatAcceleration.log10() Set the value(s) to the base 10 logarithm of the value(s).
FloatAcceleration	FloatAcceleration.log1p() Set the value(s) to the natural logarithm of the sum of the value(s) and 1.
FloatAcceleration	FloatAcceleration.minus(FloatAcceleration v) Relative scalar minus Relative scalar = Relative scalar.
FloatAcceleration	FloatAcceleration.multiplyBy(double factor) Multiply scalar with a double factor.
FloatAcceleration	FloatAcceleration.multiplyBy(float factor) Scale the value(s) by a factor.
FloatAcceleration	FloatDimensionless.Rel.multiplyBy(FloatAcceleration v) Calculate the multiplication of FloatDimensionless and FloatAcceleration, which results in a FloatAcceleration scalar.
FloatAcceleration	FloatSpeed.multiplyBy(FloatFrequency v) Calculate the multiplication of FloatSpeed and FloatFrequency, which results in a FloatAcceleration scalar.
FloatAcceleration	FloatFrequency.multiplyBy(FloatSpeed v) Calculate the multiplication of FloatFrequency and FloatSpeed, which results in a FloatAcceleration scalar.
FloatAcceleration	FloatAcceleration.plus(FloatAcceleration v) Relative scalar plus Relative scalar = Relative scalar.
FloatAcceleration	FloatAcceleration.pow(double x) Set the value(s) to the value(s) raised to the power of the argument.
FloatAcceleration	FloatAcceleration.rint() Set the value(s) to the value(s) that are closest in value to the argument and equal to a mathematical integer.
FloatAcceleration	FloatAcceleration.round() Set the value(s) to the closest long to the argument with ties rounding up.
FloatAcceleration	FloatAcceleration.signum() Set the value(s) to the signum function of the value(s); zero if the argument is zero, 1.0 if the argument is greater than zero, -1.0 if the argument is less than zero.
FloatAcceleration	FloatAcceleration.sin() Set the value(s) to the trigonometric sine of the value(s).
FloatAcceleration	FloatAcceleration.sinh() Set the value(s) to the hyperbolic sine of the value(s).
FloatAcceleration	FloatAcceleration.sqrt() Set the value(s) to the correctly rounded positive square root of the value(s).
FloatAcceleration	FloatAcceleration.tan() Set the value(s) to the trigonometric tangent of the value(s).
FloatAcceleration	FloatAcceleration.tanh() Set the value(s) to the hyperbolic tangent of the value(s).
FloatAcceleration	FloatAcceleration.toDegrees() Set the value(s) to approximately equivalent angle(s) measured in degrees.
FloatAcceleration	FloatAcceleration.toRadians() Set the value(s) to approximately equivalent angle(s) measured in radians.

Methods in org.djunits.value.vfloat.scalar with parameters of type FloatAcceleration

Modifier and Type	Method and Description
FloatTime.Rel	FloatSpeed.divideBy(FloatAcceleration v) Calculate the division of FloatSpeed and FloatAcceleration, which results in a FloatTime scalar.
FloatMass	FloatForce.divideBy(FloatAcceleration v) Calculate the division of FloatForce and FloatAcceleration, which results in a FloatMass scalar.
FloatDimensionless.Rel	FloatAcceleration.divideBy(FloatAcceleration v) Calculate the division of FloatAcceleration and FloatAcceleration, which results in a FloatDimensionless scalar.
static FloatAcceleration	FloatAcceleration.interpolate(FloatAcceleration zero, FloatAcceleration one, double ratio) Interpolate between two values.
static FloatAcceleration	FloatAcceleration.interpolate(FloatAcceleration zero, FloatAcceleration one, float ratio) Interpolate between two values.
FloatAcceleration	FloatAcceleration.minus(FloatAcceleration v) Relative scalar minus Relative scalar = Relative scalar.
FloatSpeed	FloatTime.Rel.multiplyBy(FloatAcceleration v) Calculate the multiplication of FloatTime and FloatAcceleration, which results in a FloatSpeed scalar.
FloatForce	FloatMass.multiplyBy(FloatAcceleration v) Calculate the multiplication of FloatMass and FloatAcceleration, which results in a FloatForce scalar.
FloatAcceleration	FloatDimensionless.Rel.multiplyBy(FloatAcceleration v) Calculate the multiplication of FloatDimensionless and FloatAcceleration, which results in a FloatAcceleration scalar.
FloatAcceleration	FloatAcceleration.plus(FloatAcceleration v) Relative scalar plus Relative scalar = Relative scalar.

Uses of FloatAcceleration in org.djunits.value.vfloat.vector

Methods in org.djunits.value.vfloat.vector that return FloatAcceleration

Modifier and Type	Method and Description
FloatAcceleration	MutableFloatAccelerationVector.get(int index) Retrieve the value stored at a specified index as a FloatScalar.
FloatAcceleration	FloatAccelerationVector.get(int index) Retrieve the value stored at a specified index as a FloatScalar.

Constructors in org.djunits.value.vfloat.vector with parameters of type FloatAcceleration

Constructor and Description
Dense(FloatAcceleration[] values) Construct a new Relative Dense Immutable Acceleration Vector.
Dense(FloatAcceleration[] values) Construct a new Relative Dense Immutable Acceleration Vector.
Sparse(FloatAcceleration[] values) Construct a new Relative Sparse Immutable Acceleration Vector.
Sparse(FloatAcceleration[] values) Construct a new Relative Sparse Immutable Acceleration Vector.