Mithila Muthamma PA
Coorg Institute of Technology (CIT), Coorg
Mithila Muthamma PA has created this Calculator and 400+ more calculators!
Chandana P Dev
NSS College of Engineering (NSSCE), Palakkad
Chandana P Dev has verified this Calculator and 400+ more calculators!

11 Other formulas that you can solve using the same Inputs

Length of weir or notch for velocity of approach
Length=Discharge/((2/3)*coefficient of discharging*sqrt(2*[g])*(((initial height of liquid+final height of liquid)^1.5)-(final height of liquid^1.5))) GO
Cross-sectional area when Discharge is given from Manning's equation
Cross sectional area=(Discharge*Manning’s Roughness Coefficient)/(hydraulic radius^(2/3)*Bed Slope^(1/2)) GO
Slope of Gradient of the Stream bed when Discharge is given in Manning's equation
Bed Slope=((Discharge*Manning’s Roughness Coefficient)/(Cross sectional area*(hydraulic radius^2/3)))^2 GO
Hydraulic radius when Discharge is given in Manning equation
hydraulic radius=(Discharge*Manning’s Roughness Coefficient)/(Cross sectional area*Bed Slope^1/2)^(2/3) GO
Depth at the Gauging Station
Depth at the Gauging Station=Cease-to-flow Depth+Head at the Control*(Discharge)+Terms of Order^2 GO
Length of weir or notch without velocity of approach
Length=Discharge/((2/3)*coefficient of discharging*sqrt(2*[g])*(initial height of liquid^1.5)) GO
Length of weir considering Francis's formula
Length=Discharge/(1.84*(((initial height of liquid+head due to Va)^1.5)-(head due to Va^1.5))) GO
Length of weir considering Bazin's formula without velocity approach
Length=Discharge/(0.405+(0.003/head of the liquid))*sqrt(2*[g])*(head of the liquid^1.5) GO
Velocity of piston during retraction
Velocity=Discharge/(Area of piston-Area of piston rod) GO
Estimated Distance when Discharge is given in Tracer Method
Estimated Distance=50*sqrt(Discharge) GO
Velocity of piston during extension
Velocity=Discharge/Area of piston GO

Cease-to-flow Depth when Depth at the Gauging Station given Formula

Cease-to-flow Depth=Depth at the Gauging Station-Head at the Control*(Discharge)-Terms of Order^2
h<sub>csf</sub>=h<sub>G</sub>-H<sub>c</sub>*(Q)-Q^2^2
More formulas
Depth at the Gauging Station GO
Friction Slope GO
Instantaneous Discharge when Friction Slope is given GO
Conveyance Function Determined by Manning’s Law GO
Conveyance Function determined by Chézy’s law GO
Diffusion Coefficient in Advection-diffusion flood routing GO
Discharge from Manning's equation GO
Cross-sectional area when Discharge is given from Manning's equation GO
Hydraulic Radius in Manning's formula GO
Hydraulic radius when Discharge is given in Manning equation GO
Slope of Gradient of the Stream bed when Discharge is given in Manning's equation GO
Mass flux computation GO
Instantaneous Discharge when Instantaneous Mass flux is given GO
Estimated Distance when Discharge is given in Tracer Method GO
Estimated Distance when Channel Width is given GO
Channel Width when Estimated Distance is given in Tracer Method GO
Water Table depth when Distance is given in Tracer Method GO
Surface Velocity of the river in Float Method GO
Mean River Velocity in Float Method GO
Manning’s Equation GO
Flow velocity in Continuous Discharge Measurements GO
Water Depth when Flow Velocity is given in Continuous Discharge Measurements GO

What is Gauging Station?

A stream gauge, stream gage or gauging station is a location used by hydrologists or environmental scientists to monitor and test terrestrial bodies of water.

How to Calculate Cease-to-flow Depth when Depth at the Gauging Station given?

Cease-to-flow Depth when Depth at the Gauging Station given calculator uses Cease-to-flow Depth=Depth at the Gauging Station-Head at the Control*(Discharge)-Terms of Order^2 to calculate the Cease-to-flow Depth, The Cease-to-flow depth when depth at the gauging station given formula is defined as the parameters of low flow when the hydraulics of a downstream control and a gauging station are considered. Cease-to-flow Depth and is denoted by hcsf symbol.

How to calculate Cease-to-flow Depth when Depth at the Gauging Station given using this online calculator? To use this online calculator for Cease-to-flow Depth when Depth at the Gauging Station given, enter Depth at the Gauging Station (hG), Head at the Control (Hc), Discharge (Q) and Terms of Order (Q^2) and hit the calculate button. Here is how the Cease-to-flow Depth when Depth at the Gauging Station given calculation can be explained with given input values -> -1000 = 0.05-0.05*(1)-1^2.

FAQ

What is Cease-to-flow Depth when Depth at the Gauging Station given?
The Cease-to-flow depth when depth at the gauging station given formula is defined as the parameters of low flow when the hydraulics of a downstream control and a gauging station are considered and is represented as hcsf=hG-Hc*(Q)-Q^2^2 or Cease-to-flow Depth=Depth at the Gauging Station-Head at the Control*(Discharge)-Terms of Order^2. Depth at the Gauging Station where the hydraulics of a downstream control and a gauging station are considered, Head at the Control shown as a function of discharge Q, Discharge is the rate of flow of a liquid and Terms of Order give the head loss between the gauging station and the control.
How to calculate Cease-to-flow Depth when Depth at the Gauging Station given?
The Cease-to-flow depth when depth at the gauging station given formula is defined as the parameters of low flow when the hydraulics of a downstream control and a gauging station are considered is calculated using Cease-to-flow Depth=Depth at the Gauging Station-Head at the Control*(Discharge)-Terms of Order^2. To calculate Cease-to-flow Depth when Depth at the Gauging Station given, you need Depth at the Gauging Station (hG), Head at the Control (Hc), Discharge (Q) and Terms of Order (Q^2). With our tool, you need to enter the respective value for Depth at the Gauging Station, Head at the Control, Discharge and Terms of Order 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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