Tidal Period given Change of Ebb Tidal Energy Flux across Ocean Bar Solution

STEP 0: Pre-Calculation Summary
Formula Used
Tidal Period = Change in Mean Ebb Tide Flow Energy Flux*(3*pi*Natural Depth of Ocean Bar^2*Depth of Navigation Channel^2)/(4*Maximum Instantaneous Ebb Tide Discharge^3*(Depth of Navigation Channel^2-Natural Depth of Ocean Bar^2))
T = EΔT*(3*pi*dOB^2*dNC^2)/(4*Qmax^3*(dNC^2-dOB^2))
This formula uses 1 Constants, 5 Variables
Constants Used
pi - Archimedes' constant Value Taken As 3.14159265358979323846264338327950288
Variables Used
Tidal Period - (Measured in Second) - Tidal Period is an efficient way of guesstimating how much water there is, at any given time of day, over a particular point.
Change in Mean Ebb Tide Flow Energy Flux - Change in Mean Ebb Tide Flow Energy Flux represents the alteration in the energy transferred by ebbing tidal currents over time.
Natural Depth of Ocean Bar - (Measured in Meter) - Natural Depth of Ocean Bar [L] is a shallow formation of (usually) sand that is a navigation or grounding hazard.
Depth of Navigation Channel - (Measured in Meter) - Depth of Navigation Channel [L], is the depth of a passage in a stretch of water where the sea or riverbed has been deepened to allow access to large vessels.
Maximum Instantaneous Ebb Tide Discharge - (Measured in Cubic Meter per Second) - Maximum Instantaneous Ebb Tide Discharge per unit width [length^3/time-length]. Ebb is the tidal phase during which water level is falling & flood tidal phase during which water level rises.
STEP 1: Convert Input(s) to Base Unit
Change in Mean Ebb Tide Flow Energy Flux: 161.64 --> No Conversion Required
Natural Depth of Ocean Bar: 2 Meter --> 2 Meter No Conversion Required
Depth of Navigation Channel: 4 Meter --> 4 Meter No Conversion Required
Maximum Instantaneous Ebb Tide Discharge: 2.5 Cubic Meter per Second --> 2.5 Cubic Meter per Second No Conversion Required
STEP 2: Evaluate Formula
Substituting Input Values in Formula
T = EΔT*(3*pi*dOB^2*dNC^2)/(4*Qmax^3*(dNC^2-dOB^2)) --> 161.64*(3*pi*2^2*4^2)/(4*2.5^3*(4^2-2^2))
Evaluating ... ...
T = 129.998601350721
STEP 3: Convert Result to Output's Unit
129.998601350721 Second --> No Conversion Required
FINAL ANSWER
129.998601350721 129.9986 Second <-- Tidal Period
(Calculation completed in 00.004 seconds)

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14 Methods to Predict Channel Shoaling Calculators

Change of Ebb Tidal Energy Flux across Ocean Bar between Natural and Channel Conditions
Go Change in Mean Ebb Tide Flow Energy Flux = ((4*Tidal Period)/(3*pi))*Maximum Instantaneous Ebb Tide Discharge^3*((Depth of Navigation Channel^2-Natural Depth of Ocean Bar^2)/(Natural Depth of Ocean Bar^2*Depth of Navigation Channel^2))
Maximum instantaneous Ebb Tide Discharge per unit Width
Go Maximum Instantaneous Ebb Tide Discharge = (Change in Mean Ebb Tide Flow Energy Flux*(3*pi*Natural Depth of Ocean Bar^2*Depth of Navigation Channel^2)/(4*Tidal Period*(Depth of Navigation Channel^2-Natural Depth of Ocean Bar^2)))^(1/3)
Tidal Period given Change of Ebb Tidal Energy Flux across Ocean Bar
Go Tidal Period = Change in Mean Ebb Tide Flow Energy Flux*(3*pi*Natural Depth of Ocean Bar^2*Depth of Navigation Channel^2)/(4*Maximum Instantaneous Ebb Tide Discharge^3*(Depth of Navigation Channel^2-Natural Depth of Ocean Bar^2))
Hoerls Special function Distribution
Go Hoerls Special Function Distribution = Hoerls Best-fit Coefficient a*(Filling Index^Hoerls best-fit Coefficients b)*e^(Hoerls best-fit Coefficients c*Filling Index)
Ratio of Depth of Channel to Depth at which Seaward Slope of Ocean Bar meets Sea Bottom
Go Ratio of Depth of the Channel = (Depth of Navigation Channel-Natural Depth of Ocean Bar)/(Water Depth between Sea Tip and Offshore Bottom-Natural Depth of Ocean Bar)
Water Depth where Seaward Tip of Ocean Bar meets Offshore Sea Bottom
Go Water Depth between Sea Tip and Offshore Bottom = ((Depth of Navigation Channel-Natural Depth of Ocean Bar)/Ratio of Depth of the Channel)+Natural Depth of Ocean Bar
Depth of Navigation Channel given Depth of Channel to depth at which Ocean Bar meets Sea Bottom
Go Depth of Navigation Channel = Ratio of Depth of the Channel*(Water Depth between Sea Tip and Offshore Bottom-Natural Depth of Ocean Bar)+Natural Depth of Ocean Bar
Density of Water given Water Surface Slope
Go Density of Water = (Coefficient Eckman*Shear Stress at the Water Surface)/(Water Surface Slope*[g]*Eckman Constant Depth)
Water Surface Slope
Go Water Surface Slope = (Coefficient Eckman*Shear Stress at the Water Surface)/(Density of Water*[g]*Eckman Constant Depth)
Shear Stress at Water Surface given Water Surface Slope
Go Shear Stress at the Water Surface = (Water Surface Slope*Density of Water*[g]*Eckman Constant Depth)/Coefficient Eckman
Coefficient given Water Surface Slope by Eckman
Go Coefficient Eckman = (Water Surface Slope*Density of Water*[g]*Eckman Constant Depth)/Shear Stress at the Water Surface
Transport Ratio
Go Transport Ratio = (Depth before Dredging/Depth after Dredging)^(5/2)
Depth before Dredging given Transport Ratio
Go Depth before Dredging = Depth after Dredging*Transport Ratio^(2/5)
Depth after Dredging given Transport Ratio
Go Depth after Dredging = Depth before Dredging/Transport Ratio^(2/5)

Tidal Period given Change of Ebb Tidal Energy Flux across Ocean Bar Formula

Tidal Period = Change in Mean Ebb Tide Flow Energy Flux*(3*pi*Natural Depth of Ocean Bar^2*Depth of Navigation Channel^2)/(4*Maximum Instantaneous Ebb Tide Discharge^3*(Depth of Navigation Channel^2-Natural Depth of Ocean Bar^2))
T = EΔT*(3*pi*dOB^2*dNC^2)/(4*Qmax^3*(dNC^2-dOB^2))

What is the process of Dredging?

The Dredging is the excavation of material from a water environment. Possible reasons for dredging include improving existing water features; reshaping land and water features to alter drainage.

How to Calculate Tidal Period given Change of Ebb Tidal Energy Flux across Ocean Bar?

Tidal Period given Change of Ebb Tidal Energy Flux across Ocean Bar calculator uses Tidal Period = Change in Mean Ebb Tide Flow Energy Flux*(3*pi*Natural Depth of Ocean Bar^2*Depth of Navigation Channel^2)/(4*Maximum Instantaneous Ebb Tide Discharge^3*(Depth of Navigation Channel^2-Natural Depth of Ocean Bar^2)) to calculate the Tidal Period, The Tidal Period given Change of Ebb Tidal Energy Flux across Ocean Bar is defined as a parameter influencing the Normalized, independent filling index. Because the Earth rotates through two tidal “bulges” every lunar day, coastal areas experience two high and two low tides every 24 hours and 50 minutes. Tidal Period is denoted by T symbol.

How to calculate Tidal Period given Change of Ebb Tidal Energy Flux across Ocean Bar using this online calculator? To use this online calculator for Tidal Period given Change of Ebb Tidal Energy Flux across Ocean Bar, enter Change in Mean Ebb Tide Flow Energy Flux (EΔT), Natural Depth of Ocean Bar (dOB), Depth of Navigation Channel (dNC) & Maximum Instantaneous Ebb Tide Discharge (Qmax) and hit the calculate button. Here is how the Tidal Period given Change of Ebb Tidal Energy Flux across Ocean Bar calculation can be explained with given input values -> 9.650973 = 161.64*(3*pi*2^2*4^2)/(4*2.5^3*(4^2-2^2)).

FAQ

What is Tidal Period given Change of Ebb Tidal Energy Flux across Ocean Bar?
The Tidal Period given Change of Ebb Tidal Energy Flux across Ocean Bar is defined as a parameter influencing the Normalized, independent filling index. Because the Earth rotates through two tidal “bulges” every lunar day, coastal areas experience two high and two low tides every 24 hours and 50 minutes and is represented as T = EΔT*(3*pi*dOB^2*dNC^2)/(4*Qmax^3*(dNC^2-dOB^2)) or Tidal Period = Change in Mean Ebb Tide Flow Energy Flux*(3*pi*Natural Depth of Ocean Bar^2*Depth of Navigation Channel^2)/(4*Maximum Instantaneous Ebb Tide Discharge^3*(Depth of Navigation Channel^2-Natural Depth of Ocean Bar^2)). Change in Mean Ebb Tide Flow Energy Flux represents the alteration in the energy transferred by ebbing tidal currents over time, Natural Depth of Ocean Bar [L] is a shallow formation of (usually) sand that is a navigation or grounding hazard, Depth of Navigation Channel [L], is the depth of a passage in a stretch of water where the sea or riverbed has been deepened to allow access to large vessels & Maximum Instantaneous Ebb Tide Discharge per unit width [length^3/time-length]. Ebb is the tidal phase during which water level is falling & flood tidal phase during which water level rises.
How to calculate Tidal Period given Change of Ebb Tidal Energy Flux across Ocean Bar?
The Tidal Period given Change of Ebb Tidal Energy Flux across Ocean Bar is defined as a parameter influencing the Normalized, independent filling index. Because the Earth rotates through two tidal “bulges” every lunar day, coastal areas experience two high and two low tides every 24 hours and 50 minutes is calculated using Tidal Period = Change in Mean Ebb Tide Flow Energy Flux*(3*pi*Natural Depth of Ocean Bar^2*Depth of Navigation Channel^2)/(4*Maximum Instantaneous Ebb Tide Discharge^3*(Depth of Navigation Channel^2-Natural Depth of Ocean Bar^2)). To calculate Tidal Period given Change of Ebb Tidal Energy Flux across Ocean Bar, you need Change in Mean Ebb Tide Flow Energy Flux (EΔT), Natural Depth of Ocean Bar (dOB), Depth of Navigation Channel (dNC) & Maximum Instantaneous Ebb Tide Discharge (Qmax). With our tool, you need to enter the respective value for Change in Mean Ebb Tide Flow Energy Flux, Natural Depth of Ocean Bar, Depth of Navigation Channel & Maximum Instantaneous Ebb Tide Discharge 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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