Rithik Agrawal
National Institute of Technology Karnataka (NITK), Surathkal
Rithik Agrawal has created this Calculator and 400+ more calculators!
M Naveen
National Institute of Technology (NIT), Warangal
M Naveen has verified this Calculator and 100+ more calculators!

11 Other formulas that you can solve using the same Inputs

Maximum and Center Deflection of Simply Supported Beam carrying UDL over its entire Length
Deflection=(5*Uniformly Distributed Load*(Length^4))/(384*Modulus Of Elasticity*Area Moment of Inertia) GO
Condition for Maximum Moment in Interior Spans of Beams
Point of Maximum Moment=(Length/2)-(Maximum Bending Moment/(Uniformly Distributed Load*1000*Length)) GO
Tension at Supports for UDL on Parabolic Cable is Given
Tension at Supports=sqrt((Midspan Tension^2)+(Uniformly Distributed Load*Length of Cable/2)^2) GO
Tension at Midspan when Tension at Supports for UDL on Parabolic Cable is Given
Midspan Tension=sqrt((Tension at Supports^2)-(((Uniformly Distributed Load*Cable Span)/2)^2)) GO
Maximum Sag when Tension at Midspan for UDL on Parabolic Cable is Given
Maximum Sag=Uniformly Distributed Load*(Length of Cable^2)/(8*Midspan Tension) GO
UDL when Tension at Midspan for UDL on Parabolic Cable is Given
Uniformly Distributed Load=8*Midspan Tension*Maximum Sag/(Length of Cable^2) GO
Tension at Midspan for UDL on Parabolic Cable
Midspan Tension=(Uniformly Distributed Load*(Cable Span^2))/(8*Maximum Sag) GO
Span of Cable when Tension at Midspan for UDL on Parabolic Cable is Given
Cable Span=sqrt(8*Midspan Tension*Maximum Sag/Uniformly Distributed Load) GO
Fixed End Moment of a Fixed Beam having UDL over its entire Length
Fixed End Moment =(Uniformly Distributed Load*(Length^2))/12 GO
Bending Moment of a Cantilever Subject to UDL Over its Entire Span
Bending Moment =(-Uniformly Distributed Load*Length^2)/2 GO
Bending Moment of Simply Supported Beams with Uniformly Distributed Load
Bending Moment =(Uniformly Distributed Load*Length^2)/8 GO

Parabolic Equation for the Cable Slope Formula

Parabolic Equation of Cable Slope=Uniformly Distributed Load*(Distance from Midpoint of Cable^2)/(2*Midspan Tension)
y=q*(x^2)/(2*H)
More formulas
Allowable Stress for Compression Elements for Highway Bridges GO
Tension at Midspan for UDL on Parabolic Cable GO
Span of Cable when Tension at Midspan for UDL on Parabolic Cable is Given GO
Maximum Sag when Tension at Midspan for UDL on Parabolic Cable is Given GO
Tension at Supports for UDL on Parabolic Cable is Given GO
Tension at Midspan when Tension at Supports for UDL on Parabolic Cable is Given GO
UDL when Tension at Supports for UDL on Parabolic Cable is Given GO
Span of Cable when Tension at Supports for UDL on Parabolic Cable is Given GO
Length of Cable for UDL on Parabolic Cable is Given GO
Span of Cable when Length of Cable for UDL on Parabolic Cable is Given GO
Maximum Sag when Length of Cable for UDL on Parabolic Cable is Given GO

What is Cable ?

A cable is a thick wire, or a group of wires inside a rubber or plastic covering, which is used to carry electricity or electronic signals. Cable is used to refer to television systems in which the signals are sent along underground wires rather than by radio waves.

How to Calculate Parabolic Equation for the Cable Slope?

Parabolic Equation for the Cable Slope calculator uses Parabolic Equation of Cable Slope=Uniformly Distributed Load*(Distance from Midpoint of Cable^2)/(2*Midspan Tension) to calculate the Parabolic Equation of Cable Slope, The Parabolic Equation for the Cable Slope is defined as general equation representing the curve of loading. Parabolic Equation of Cable Slope and is denoted by y symbol.

How to calculate Parabolic Equation for the Cable Slope using this online calculator? To use this online calculator for Parabolic Equation for the Cable Slope, enter Uniformly Distributed Load (q), Distance from Midpoint of Cable (x) and Midspan Tension (H) and hit the calculate button. Here is how the Parabolic Equation for the Cable Slope calculation can be explained with given input values -> 50000 = 10000*(10^2)/(2*10).

FAQ

What is Parabolic Equation for the Cable Slope?
The Parabolic Equation for the Cable Slope is defined as general equation representing the curve of loading and is represented as y=q*(x^2)/(2*H) or Parabolic Equation of Cable Slope=Uniformly Distributed Load*(Distance from Midpoint of Cable^2)/(2*Midspan Tension). Uniformly distributed load is a force applied over an area or length, denoted by q which is force per unit length, Distance from Midpoint of Cable is horizontal distance where vertical length is to be calculated and Midspan Tension is the total tension acting in cable at midpoint.
How to calculate Parabolic Equation for the Cable Slope?
The Parabolic Equation for the Cable Slope is defined as general equation representing the curve of loading is calculated using Parabolic Equation of Cable Slope=Uniformly Distributed Load*(Distance from Midpoint of Cable^2)/(2*Midspan Tension). To calculate Parabolic Equation for the Cable Slope, you need Uniformly Distributed Load (q), Distance from Midpoint of Cable (x) and Midspan Tension (H). With our tool, you need to enter the respective value for Uniformly Distributed Load, Distance from Midpoint of Cable and Midspan Tension and hit the calculate button. You can also select the units (if any) for Input(s) and the Output as well.
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