10 Other formulas that you can solve using the same Inputs

Ultimate Strength for Symmetrical Reinforcement in Single Layers
Axial Load Capacity=Capacity reduction factor*((Area of Compressive Reinforcement*Yield strength of reinforcing steel/((Eccentricity/Distance from Compression to Tensile Reinforcement)-Distance from Compression to Centroid Reinforcment+0.5))+(Width of compression face*Depth of column*28 Day Compressive Strength of Concrete/((3*Depth of column*Eccentricity/(Distance from Compression to Tensile Reinforcement^2))+1.18))) GO
Theoretical Maximum Stress for Secant Code Steels
Critical stress=Yield Strength/(1+((Eccentricity*End Fixity Coefficient/(Radius of gyration^2))*(sec((1/Radius of gyration)*sqrt(Concentrated load/(4*Cross sectional area*Modulus Of Elasticity)))))) GO
Maximum Stress For a Circular Cross Section
Maximum stress for a section=Axial Stress*(1+8*Eccentricity/Diameter ) GO
Maximum Stress For a Rectangular Cross Section
Maximum stress for a section=Axial Stress*(1+6*Eccentricity/Width) GO
Semi-latus rectum of an ellipse when eccentricity is given
Semi-latus rectum=Semi-major axis*(1-(Eccentricity)^2) GO
Balanced Moment when Load and Eccentricity is Given
Balanced Moment=Eccentricity*Load Balanced Condition GO
Linear eccentricity of an ellipse when eccentricity and semimajor axis are given
Linear Eccentricity=(Eccentricity*Semi-major axis) GO
Linear eccentricity of ellipse when eccentricity and major axis are given
Linear Eccentricity=Eccentricity*Major axis GO
Directrix of an ellipse(a>b)
Directrix=Major axis/Eccentricity GO
Directrix of an ellipse(b>a)
Directrix=Major axis/Eccentricity GO

4 Other formulas that calculate the same Output

Latus Rectum of hyperbola
Latus Rectum=(2*(Minor axis)^2)/(Major axis) GO
Latus Rectum of an ellipse (a>b)
Latus Rectum=2*(Minor axis)^2/(Major axis) GO
Latus Rectum of an ellipse (b>a)
Latus Rectum=2*(Minor axis)^2/Major axis GO
Length of latus rectum of parabola
Latus Rectum=4*Focus GO

Latus rectum of an ellipse when focal parameter is given Formula

Latus Rectum=Focal parameter of an ellipse*Eccentricity
More formulas
Eccentricity of an ellipse (a>b) GO
Eccentricity of an ellipse (b>a) GO
Directrix of an ellipse(a>b) GO
Directrix of an ellipse(b>a) GO
Latus Rectum of an ellipse (a>b) GO
Latus Rectum of an ellipse (b>a) GO
Length of major axis of an ellipse (a>b) GO
Length of the major axis of an ellipse (b>a) GO
Length of minor axis of an ellipse (a>b) GO
Length of minor axis of an ellipse (b>a) GO
Linear eccentricity of an ellipse GO
Semi-latus rectum of an ellipse GO
Eccentricity of an ellipse when linear eccentricity is given GO
Semi-major axis of an ellipse GO
Semi-minor axis of an ellipse GO
Linear eccentricity of ellipse when eccentricity and major axis are given GO
Linear eccentricity of an ellipse when eccentricity and semimajor axis are given GO
Semi-latus rectum of an ellipse when eccentricity is given GO
Area of Ellipse GO
Circumference of Ellipse GO
Axis 'a' of Ellipse when Area is given GO
Axis 'b' of Ellipse when area is given GO
Length of radius vector from center in given direction whose angle is theta in ellipse GO

What is latus rectum of an ellipse and how it is calculated?

Latus rectum of an ellipse when the focal parameter is given is a chord in an ellipse that passes through a focus and is parallel to the directrix. It is calculated by the formula, l = pe where l is the latus rectum of the ellipse, p is the focal parameter of an ellipse, e is the eccentricity of an ellipse.

How to Calculate Latus rectum of an ellipse when focal parameter is given?

Latus rectum of an ellipse when focal parameter is given calculator uses Latus Rectum=Focal parameter of an ellipse*Eccentricity to calculate the Latus Rectum, Latus rectum of an ellipse when focal parameter is given is a chord in an ellipse that passes through a focus and is parallel to the directrix. . Latus Rectum and is denoted by L symbol.

How to calculate Latus rectum of an ellipse when focal parameter is given using this online calculator? To use this online calculator for Latus rectum of an ellipse when focal parameter is given, enter Focal parameter of an ellipse (f) and Eccentricity (e) and hit the calculate button. Here is how the Latus rectum of an ellipse when focal parameter is given calculation can be explained with given input values -> 0.125 = 1.25*0.1.

FAQ

What is Latus rectum of an ellipse when focal parameter is given?
Latus rectum of an ellipse when focal parameter is given is a chord in an ellipse that passes through a focus and is parallel to the directrix. and is represented as L=f*e or Latus Rectum=Focal parameter of an ellipse*Eccentricity. Focal parameter of an ellipse is the distance between directrix and focus and Eccentricity of an ellipse is a non-negative real number that uniquely characterizes its shape.
How to calculate Latus rectum of an ellipse when focal parameter is given?
Latus rectum of an ellipse when focal parameter is given is a chord in an ellipse that passes through a focus and is parallel to the directrix. is calculated using Latus Rectum=Focal parameter of an ellipse*Eccentricity. To calculate Latus rectum of an ellipse when focal parameter is given, you need Focal parameter of an ellipse (f) and Eccentricity (e). With our tool, you need to enter the respective value for Focal parameter of an ellipse and Eccentricity and hit the calculate button. You can also select the units (if any) for Input(s) and the Output as well.
How many ways are there to calculate Latus Rectum?
In this formula, Latus Rectum uses Focal parameter of an ellipse and Eccentricity. We can use 4 other way(s) to calculate the same, which is/are as follows -
  • Latus Rectum=2*(Minor axis)^2/(Major axis)
  • Latus Rectum=2*(Minor axis)^2/Major axis
  • Latus Rectum=(2*(Minor axis)^2)/(Major axis)
  • Latus Rectum=4*Focus
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