Shweta Patil
Walchand College of Engineering (WCE), Sangli
Shweta Patil has created this Calculator and 500+ more calculators!
Shashwati Tidke
Vishwakarma Institute of Technology (VIT), Pune
Shashwati Tidke has verified this Calculator and 200+ more calculators!

11 Other formulas that you can solve using the same Inputs

Direction cosine w.r.to x axis given direction ratio 1,2 & 3
Direction cosine with respect to z axis= (Direction ratio 1)/sqrt((Direction ratio 1)^2+(Direction ratio 2)^2+(Direction ratio 3)^2) GO
Direction cosine w.r.to y axis given direction ratio 1,2 & 3
Direction cosine with respect to y axis= (Direction ratio 2)/sqrt((Direction ratio 1)^2+(Direction ratio 2)^2+(Direction ratio 3)^2) GO
Direction cosine w.r.to z axis given direction ratio 1,2 & 3
Direction cosine with respect to z axis= (Direction ratio 3)/sqrt((Direction ratio 1)^2+(Direction ratio 2)^2+(Direction ratio 3)^2) GO
x1 coordinate of end point of line given direction ratio and x2 coordinate of other end of that line
x1 coordinate in 3D space= Direction ratio 1-x2 coordinate in 3D space GO
x2 coordinate of end point of line given direction ratio and x1 coordinate of other end of that line
x2 coordinate in 3D space= Direction ratio 1-x1 coordinate in 3D space GO
y1 coordinate of end point of line given direction ratio and y2 coordinate of other end of that line
y1 coordinate in 3D space= Direction ratio 1-y2 coordinate in 3D space GO
y2 coordinate of end point of line given direction ratio and y1 coordinate of other end of that line
y2 coordinate in 3D space= Direction ratio 1-y1 coordinate in 3D space GO
z1 coordinate of end point of line given direction ratio and z2 coordinate of other end of that line
z1 coordinate in 3D space= Direction ratio 1-z2 coordinate in 3D space GO
z2 coordinate of end point of line given direction ratio and z1 coordinate of other end of that line
z2 coordinate in 3D space= Direction ratio 1-z1 coordinate in 3D space GO
Projection of line on z axis given length of line & direction ratio of line w.r.to z axis
projection of line=(Direction ratio 3*Length) GO
Projection of line on y axis given length of line & direction ratio of line w.r.to y axis
projection of line=(Direction ratio 2*Length) GO

11 Other formulas that calculate the same Output

Length over which Deformation Takes Place when Strain Energy in Torsion is Given
Length=sqrt(2*Strain Energy*Polar moment of Inertia*Shear Modulus of Elasticity/Torque^2) GO
Length over which Deformation Takes Place when Strain Energy in Shear is Given
Length=2*Strain Energy*Shear Area*Shear Modulus of Elasticity/(Shear Force^2) GO
Length of rectangle when diagonal and breadth are given
Length=sqrt(Diagonal^2-Breadth^2) GO
Length of rectangle when perimeter and breadth are given
Length=(Perimeter-2*Breadth)/2 GO
Length of rectangle when diagonal and angle between two diagonal are given
Length=Diagonal*sin(sinϑ/2) GO
Length of a rectangle in terms of diagonal and angle between diagonal and breadth
Length=Diagonal*sin(sinϑ) GO
Length of rectangle when area and breadth are given
Length=Area/Breadth GO
Length of the major axis of an ellipse (b>a)
Length=2*Major axis GO
Length of major axis of an ellipse (a>b)
Length=2*Major axis GO
Length of minor axis of an ellipse (a>b)
Length=2*Minor axis GO
Length of minor axis of an ellipse (b>a)
Length=2*Minor axis GO

Distance between plane in normal formal and a point Formula

Length=modulus((Direction ratio 1*x coordinate in 3D space)+(Direction ratio 2*y coordinate in 3D space)+(Direction ratio 3*z coordinate in 3D space)-(constant coefficient of plane))
l=modulus((d1*x)+(d2*y)+(d3*z)-(p))
More formulas
Distance between two points P(x1,y1,z1) & Q(x2,y2,z2) GO
Distance of a point from origin GO
Perpendicular distance of a point from z axis given x & y coordinate of that point GO
Perpendicular distance of a point from y axis given x & z coordinate of that point GO
Perpendicular distance of a point from x axis given y & z coordinate of that point GO
Projection of a line PQ given direction cosines of line AB making angle with line PQ GO
Projection of a line on x axis GO
Projection of a line on y axis GO
Projection of a line on z axis GO
length of line given projections of that line on x, y & z axis GO
Projection of line on z axis given length of line & direction ratio of line w.r.to z axis GO
Projection of line on y axis given length of line & direction ratio of line w.r.to y axis GO
Projection of line on x axis given length of line & direction ratio of line w.r.to x axis GO
length of line given direction ratio and projection of line w.r.to x axis GO
length of line given direction ratio and projection of line w.r.to y axis GO
length of line given direction ratio and projection of line w.r.to z axis GO
⊥ distance from the origin to the plane given direction cosine w.r.to z axis GO
⊥ distance from the origin to the plane given direction cosine w.r.to y axis GO
⊥ distance from the origin to the plane given direction cosine w.r.to x axis GO
⊥ distance from the origin to the plane given direction cosines of normal from origin to plane GO
Distance of a point from plane GO
distance between 2 || planes of form ax + by + cz + d1 = 0 & ax + by + cz + d2 = 0 GO
radius of sphere of form (x – a)2 + (y – b)2 + (z – c)2 = r2 GO
radius of sphere of form x2 + y2 + z2 + 2ux + 2vy + 2wz + d = 0 GO
Radius of sphere of form x2+y2+z2+(2u/a)x+(2v/a)y+(2w/a)z+ d/a=0 GO
D in std equation of a plane given dist. b/w || planes,D.R.s taking dist. -ve GO

What is plane?

A plane is a surface such that, if two points are taken on it, a straight line joining them lies wholly in the surface. The coefficient of x, y and z in the cartesian equation of a plane are the direction ratios of normal to the plane.

How to Calculate Distance between plane in normal formal and a point?

Distance between plane in normal formal and a point calculator uses Length=modulus((Direction ratio 1*x coordinate in 3D space)+(Direction ratio 2*y coordinate in 3D space)+(Direction ratio 3*z coordinate in 3D space)-(constant coefficient of plane)) to calculate the Length, The Distance between plane in normal formal and a point formula is defined as length measured from plane lx + my + nz = p. and a point. Length and is denoted by l symbol.

How to calculate Distance between plane in normal formal and a point using this online calculator? To use this online calculator for Distance between plane in normal formal and a point, enter Direction ratio 1 (d1), x coordinate in 3D space (x), Direction ratio 2 (d2), y coordinate in 3D space (y), Direction ratio 3 (d3), z coordinate in 3D space (z) and constant coefficient of plane (p) and hit the calculate button. Here is how the Distance between plane in normal formal and a point calculation can be explained with given input values -> 1.9 = modulus((0.7*2)+(0.2*5)+(0.5*3)-(2)).

FAQ

What is Distance between plane in normal formal and a point?
The Distance between plane in normal formal and a point formula is defined as length measured from plane lx + my + nz = p. and a point and is represented as l=modulus((d1*x)+(d2*y)+(d3*z)-(p)) or Length=modulus((Direction ratio 1*x coordinate in 3D space)+(Direction ratio 2*y coordinate in 3D space)+(Direction ratio 3*z coordinate in 3D space)-(constant coefficient of plane)). Direction ratio 1 is ratio proportional to direction cosine w.r.to x axis, x coordinate in 3D space is defined as the a point on x axis, Direction ratio 2 is ratio proportional to direction cosine w.r.to y axis, y coordinate in 3D space is defined as the a point on y axis, Direction ratio 3 is ratio proportional to direction cosine w.r.to z axis, z coordinate in 3D space is defined as the a point on z axis and constant coefficient of plane is defined as a number which is constant in plane of form lx + my + nz = p.
How to calculate Distance between plane in normal formal and a point?
The Distance between plane in normal formal and a point formula is defined as length measured from plane lx + my + nz = p. and a point is calculated using Length=modulus((Direction ratio 1*x coordinate in 3D space)+(Direction ratio 2*y coordinate in 3D space)+(Direction ratio 3*z coordinate in 3D space)-(constant coefficient of plane)). To calculate Distance between plane in normal formal and a point, you need Direction ratio 1 (d1), x coordinate in 3D space (x), Direction ratio 2 (d2), y coordinate in 3D space (y), Direction ratio 3 (d3), z coordinate in 3D space (z) and constant coefficient of plane (p). With our tool, you need to enter the respective value for Direction ratio 1, x coordinate in 3D space, Direction ratio 2, y coordinate in 3D space, Direction ratio 3, z coordinate in 3D space and constant coefficient of plane 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 Length?
In this formula, Length uses Direction ratio 1, x coordinate in 3D space, Direction ratio 2, y coordinate in 3D space, Direction ratio 3, z coordinate in 3D space and constant coefficient of plane. We can use 11 other way(s) to calculate the same, which is/are as follows -
  • Length=sqrt(Diagonal^2-Breadth^2)
  • Length=Area/Breadth
  • Length=(Perimeter-2*Breadth)/2
  • Length=Diagonal*sin(sinϑ)
  • Length=Diagonal*sin(sinϑ/2)
  • Length=2*Major axis
  • Length=2*Major axis
  • Length=2*Minor axis
  • Length=2*Minor axis
  • Length=2*Strain Energy*Shear Area*Shear Modulus of Elasticity/(Shear Force^2)
  • Length=sqrt(2*Strain Energy*Polar moment of Inertia*Shear Modulus of Elasticity/Torque^2)
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