Package org.djunits.value.vfloat.scalar

Class FloatEnergy

java.lang.Object
java.lang.Number
org.djunits.value.base.Scalar<U,S>
org.djunits.value.vfloat.scalar.base.FloatScalar<U,R>
org.djunits.value.vfloat.scalar.base.FloatScalarRel<EnergyUnit,FloatEnergy>
org.djunits.value.vfloat.scalar.FloatEnergy
All Implemented Interfaces:
Serializable, Cloneable, Comparable<FloatEnergy>, Relative<EnergyUnit,FloatEnergy>, Value<EnergyUnit,FloatEnergy>
@Generated(value="org.djunits.generator.GenerateDJUNIT", date="2023-07-23T14:06:38.224104100Z") public class FloatEnergy extends FloatScalarRel<EnergyUnit,FloatEnergy>
Easy access methods for the FloatEnergy FloatScalar, which is relative by definition.

Copyright (c) 2013-2024 Delft University of Technology, PO Box 5, 2600 AA, Delft, the Netherlands. All rights reserved.
BSD-style license. See DJUNITS License.

Author:
Alexander Verbraeck, Peter Knoppers
See Also:

  • Field Details

    • ZERO

      public static final FloatEnergy ZERO
      Constant with value zero.

    • ONE

      public static final FloatEnergy ONE
      Constant with value one.

    • NaN

      public static final FloatEnergy NaN
      Constant with value NaN.

    • POSITIVE_INFINITY

      public static final FloatEnergy POSITIVE_INFINITY
      Constant with value POSITIVE_INFINITY.

    • NEGATIVE_INFINITY

      public static final FloatEnergy NEGATIVE_INFINITY
      Constant with value NEGATIVE_INFINITY.

    • POS_MAXVALUE

      public static final FloatEnergy POS_MAXVALUE
      Constant with value MAX_VALUE.

    • NEG_MAXVALUE

      public static final FloatEnergy NEG_MAXVALUE
      Constant with value -MAX_VALUE.

  • Constructor Details

    • FloatEnergy

      public FloatEnergy(float value, EnergyUnit unit)
      Construct FloatEnergy scalar.
      Parameters:
      value - float; the float value
      unit - unit for the float value

    • FloatEnergy

      public FloatEnergy(FloatEnergy value)
      Construct FloatEnergy scalar.
      Parameters:
      value - Scalar from which to construct this instance

    • FloatEnergy

      public FloatEnergy(double value, EnergyUnit unit)
      Construct FloatEnergy scalar using a double value.
      Parameters:
      value - double; the double value
      unit - unit for the resulting float value

  • Method Details

    • instantiateRel

      public final FloatEnergy instantiateRel(float value, EnergyUnit unit)
      Construct a new Relative Immutable FloatScalar of the right type. Each extending class must implement this method.
      Specified by:
      instantiateRel in class FloatScalarRel<EnergyUnit,FloatEnergy>
      Parameters:
      value - float; the float value
      unit - U; the unit
      Returns:
      R a new relative instance of the FloatScalar of the right type

    • instantiateSI

      public static final FloatEnergy instantiateSI(float value)
      Construct FloatEnergy scalar.
      Parameters:
      value - float; the float value in SI units
      Returns:
      the new scalar with the SI value

    • interpolate

      public static FloatEnergy interpolate(FloatEnergy zero, FloatEnergy one, float ratio)
      Interpolate between two values.
      Parameters:
      zero - the low value
      one - the high value
      ratio - double; the ratio between 0 and 1, inclusive
      Returns:
      a Scalar at the ratio between

    • max

      public static FloatEnergy max(FloatEnergy r1, FloatEnergy r2)
      Return the maximum value of two relative scalars.
      Parameters:
      r1 - the first scalar
      r2 - the second scalar
      Returns:
      the maximum value of two relative scalars

    • max

      public static FloatEnergy max(FloatEnergy r1, FloatEnergy r2, FloatEnergy... rn)
      Return the maximum value of more than two relative scalars.
      Parameters:
      r1 - the first scalar
      r2 - the second scalar
      rn - the other scalars
      Returns:
      the maximum value of more than two relative scalars

    • min

      public static FloatEnergy min(FloatEnergy r1, FloatEnergy r2)
      Return the minimum value of two relative scalars.
      Parameters:
      r1 - the first scalar
      r2 - the second scalar
      Returns:
      the minimum value of two relative scalars

    • min

      public static FloatEnergy min(FloatEnergy r1, FloatEnergy r2, FloatEnergy... rn)
      Return the minimum value of more than two relative scalars.
      Parameters:
      r1 - the first scalar
      r2 - the second scalar
      rn - the other scalars
      Returns:
      the minimum value of more than two relative scalars

    • valueOf

      public static FloatEnergy valueOf(String text)
      Returns a FloatEnergy representation of a textual representation of a value with a unit. The String representation that can be parsed is the double value in the unit, followed by a localized or English abbreviation of the unit. Spaces are allowed, but not required, between the value and the unit.
      Parameters:
      text - String; the textual representation to parse into a FloatEnergy
      Returns:
      FloatEnergy; the Scalar representation of the value in its unit
      Throws:
      IllegalArgumentException - when the text cannot be parsed
      NullPointerException - when the text argument is null

    • of

      public static FloatEnergy of(float value, String unitString)
      Returns a FloatEnergy based on a value and the textual representation of the unit, which can be localized.
      Parameters:
      value - double; the value to use
      unitString - String; the textual representation of the unit
      Returns:
      FloatEnergy; the Scalar representation of the value in its unit
      Throws:
      IllegalArgumentException - when the unit cannot be parsed or is incorrect
      NullPointerException - when the unitString argument is null

    • divide

      public final FloatDimensionless divide(FloatEnergy v)
      Calculate the division of FloatEnergy and FloatEnergy, which results in a FloatDimensionless scalar.
      Parameters:
      v - FloatEnergy; scalar
      Returns:
      FloatDimensionless; scalar as a division of FloatEnergy and FloatEnergy

    • divide

      public final FloatLength divide(FloatForce v)
      Calculate the division of FloatEnergy and FloatForce, which results in a FloatLength scalar.
      Parameters:
      v - FloatEnergy; scalar
      Returns:
      FloatLength; scalar as a division of FloatEnergy and FloatForce

    • divide

      public final FloatForce divide(FloatLength v)
      Calculate the division of FloatEnergy and FloatLength, which results in a FloatForce scalar.
      Parameters:
      v - FloatEnergy; scalar
      Returns:
      FloatForce; scalar as a division of FloatEnergy and FloatLength

    • times

      public final FloatForce times(FloatLinearDensity v)
      Calculate the multiplication of FloatEnergy and FloatLinearDensity, which results in a FloatForce scalar.
      Parameters:
      v - FloatEnergy; scalar
      Returns:
      FloatForce; scalar as a multiplication of FloatEnergy and FloatLinearDensity

    • divide

      public final FloatPower divide(FloatDuration v)
      Calculate the division of FloatEnergy and FloatDuration, which results in a FloatPower scalar.
      Parameters:
      v - FloatEnergy; scalar
      Returns:
      FloatPower; scalar as a division of FloatEnergy and FloatDuration

    • divide

      public final FloatDuration divide(FloatPower v)
      Calculate the division of FloatEnergy and FloatPower, which results in a FloatDuration scalar.
      Parameters:
      v - FloatEnergy; scalar
      Returns:
      FloatDuration; scalar as a division of FloatEnergy and FloatPower

    • divide

      public final FloatPressure divide(FloatVolume v)
      Calculate the division of FloatEnergy and FloatVolume, which results in a FloatPressure scalar.
      Parameters:
      v - FloatEnergy; scalar
      Returns:
      FloatPressure; scalar as a division of FloatEnergy and FloatVolume

    • divide

      public final FloatVolume divide(FloatPressure v)
      Calculate the division of FloatEnergy and FloatPressure, which results in a FloatVolume scalar.
      Parameters:
      v - FloatEnergy; scalar
      Returns:
      FloatVolume; scalar as a division of FloatEnergy and FloatPressure

    • times

      public final FloatPower times(FloatFrequency v)
      Calculate the multiplication of FloatEnergy and FloatFrequency, which results in a FloatPower scalar.
      Parameters:
      v - FloatEnergy; scalar
      Returns:
      FloatPower; scalar as a multiplication of FloatEnergy and FloatFrequency

    • divide

      public final FloatMomentum divide(FloatSpeed v)
      Calculate the division of FloatEnergy and FloatSpeed, which results in a FloatMomentum scalar.
      Parameters:
      v - FloatEnergy; scalar
      Returns:
      FloatMomentum; scalar as a division of FloatEnergy and FloatSpeed

    • divide

      public final FloatSpeed divide(FloatMomentum v)
      Calculate the division of FloatEnergy and FloatMomentum, which results in a FloatSpeed scalar.
      Parameters:
      v - FloatEnergy; scalar
      Returns:
      FloatSpeed; scalar as a division of FloatEnergy and FloatMomentum

    • reciprocal

      public FloatSIScalar reciprocal()
      Create the reciprocal of this scalar with the correct dimensions.
      Specified by:
      reciprocal in class FloatScalarRel<EnergyUnit,FloatEnergy>
      Returns:
      FloatScalar<?>; a new scalar instance with correct SI dimensions