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Water Depth given Energy Dissipation Rate per unit Surface Area due to Wave Breaking Formula

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GoWater Depth given Stable Wave Height Formula

3

GoWater Depth given Maximum Wave Height by Miche Criterion Formula

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Water Depth of the considered catchment is the depth as measured from the water level to the bottom of the considered water body. Check FAQs

d = K d \cdot \frac{E'' \cdot C g - (E f)}{δ}

d - Water Depth?K_d - Decay Coefficient?E^'' - Wave Energy?C_g - Wave Group Speed?E_f - Energy Flux associated with Stable Wave Height?δ - Energy Dissipation Rate per unit Surface Area?

Water Depth given Energy Dissipation Rate per unit Surface Area due to Wave Breaking Example

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Here is how the Water Depth given Energy Dissipation Rate per unit Surface Area due to Wave Breaking equation looks like with Values.

Here is how the Water Depth given Energy Dissipation Rate per unit Surface Area due to Wave Breaking equation looks like with Units.

Here is how the Water Depth given Energy Dissipation Rate per unit Surface Area due to Wave Breaking equation looks like.

1.0039 = 10.15 \cdot \frac{20 \cdot 100 - (99)}{19221}

1.0039m = 10.15 \cdot \frac{20J/m² \cdot 100m/s - (99)}{19221}

1.0039 = 10.15 \cdot \frac{20 \cdot 100 - (99)}{19221}

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Water Depth given Energy Dissipation Rate per unit Surface Area due to Wave Breaking Solution

Follow our step by step solution on how to calculate Water Depth given Energy Dissipation Rate per unit Surface Area due to Wave Breaking?

FIRST Step Consider the formula

d = K d \cdot \frac{E'' \cdot C g - (E f)}{δ}

Next Step Substitute values of Variables

∴

d = 10.15 \cdot \frac{20J/m² \cdot 100m/s - (99)}{19221}

Next Step Prepare to Evaluate

∴

d = 10.15 \cdot \frac{20 \cdot 100 - (99)}{19221}

Next Step Evaluate

∴

d = 1.00385775974195m

LAST Step Rounding Answer

∴

d = 1.0039m

Water Depth given Energy Dissipation Rate per unit Surface Area due to Wave Breaking Formula Elements

Variables

Water Depth

Water Depth of the considered catchment is the depth as measured from the water level to the bottom of the considered water body.

Symbol: d

Measurement: LengthUnit: m

Note: Value can be positive or negative.

Formulas to find Water Depth

Open Variable

Decay Coefficient

Decay Coefficient is the loss in cell mass due to the oxidation of internal storage products for energy for cell maintenance.

Symbol: K_d

Measurement: NAUnit: Unitless

Note: Value should be greater than 0.

Formulas to find Decay Coefficient

Open Variable

Wave Energy

Wave Energy is the ratio of power per unit crest length to wave group speed.

Symbol: E^''

Measurement: Heat DensityUnit: J/m²

Note: Value should be greater than 0.

Formulas to find Wave Energy

Open Variable

Wave Group Speed

Wave Group Speed of a wave is the velocity with which the overall envelope shape of the wave's amplitudes.

Symbol: C_g

Measurement: SpeedUnit: m/s

Note: Value should be greater than 0.

Formulas to find Wave Group Speed

Open Variable

Energy Flux associated with Stable Wave Height

Energy Flux associated with Stable Wave Height is the rate of transfer of energy through a surface.

Symbol: E_f

Measurement: NAUnit: Unitless

Note: Value should be greater than 0.

Formulas to find Energy Flux associated with Stable Wave Height

Open Variable

Energy Dissipation Rate per unit Surface Area

Energy Dissipation Rate per unit Surface Area is the amount of energy lost by the viscous forces per unit surface area.

Symbol: δ

Measurement: NAUnit: Unitless

Note: Value should be greater than 0.

Formulas to find Energy Dissipation Rate per unit Surface Area

Open Variable

Other Formulas to find Water Depth

Go Water Depth given Stable Wave Height

d = \frac{H stable}{0.4}

Go Water Depth given Maximum Wave Height by Miche Criterion

d = (\frac{a \tanh (\frac{H max}{0.14 \cdot λ})}{k})

Other formulas in Energy Flux Method category

Go Energy Flux associated with Stable Wave Height

E f' = E'' \cdot C g

Go Energy Dissipation Rate per unit Surface Area due to Wave Breaking

δ = (\frac{K d}{d}) \cdot ((E'' \cdot C g) - (E f))

Go Stable Wave Height

H stable = 0.4 \cdot d

Go Energy Dissipation Rate by Battjes and Janssen

δ = 0.25 \cdot ρ water \cdot [g] \cdot Q B \cdot f m \cdot ({H max}^{2})

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How to Evaluate Water Depth given Energy Dissipation Rate per unit Surface Area due to Wave Breaking?

Water Depth given Energy Dissipation Rate per unit Surface Area due to Wave Breaking evaluator uses Water Depth = Decay Coefficient*(Wave Energy*Wave Group Speed-(Energy Flux associated with Stable Wave Height))/Energy Dissipation Rate per unit Surface Area to evaluate the Water Depth, The Water Depth given Energy Dissipation Rate per unit Surface Area due to Wave Breaking formula is defined as a measure by soundings usually acquired by hydrographic surveys, measured from the water level to the bottom surface. Water Depth is denoted by d symbol.

How to evaluate Water Depth given Energy Dissipation Rate per unit Surface Area due to Wave Breaking using this online evaluator? To use this online evaluator for Water Depth given Energy Dissipation Rate per unit Surface Area due to Wave Breaking, enter Decay Coefficient (K_d), Wave Energy (E^''), Wave Group Speed (C_g), Energy Flux associated with Stable Wave Height (E_f) & Energy Dissipation Rate per unit Surface Area (δ) and hit the calculate button.

FAQs on Water Depth given Energy Dissipation Rate per unit Surface Area due to Wave Breaking

What is the formula to find Water Depth given Energy Dissipation Rate per unit Surface Area due to Wave Breaking?

The formula of Water Depth given Energy Dissipation Rate per unit Surface Area due to Wave Breaking is expressed as Water Depth = Decay Coefficient*(Wave Energy*Wave Group Speed-(Energy Flux associated with Stable Wave Height))/Energy Dissipation Rate per unit Surface Area. Here is an example- 1.003858 = 10.15*(20*100-(99))/19221.

How to calculate Water Depth given Energy Dissipation Rate per unit Surface Area due to Wave Breaking?

With Decay Coefficient (K_d), Wave Energy (E^''), Wave Group Speed (C_g), Energy Flux associated with Stable Wave Height (E_f) & Energy Dissipation Rate per unit Surface Area (δ) we can find Water Depth given Energy Dissipation Rate per unit Surface Area due to Wave Breaking using the formula - Water Depth = Decay Coefficient*(Wave Energy*Wave Group Speed-(Energy Flux associated with Stable Wave Height))/Energy Dissipation Rate per unit Surface Area.

What are the other ways to Calculate Water Depth?

Here are the different ways to Calculate Water Depth-

Water Depth=Stable Wave Height/0.4
Water Depth=((atanh(Maximum Wave Height/(0.14*Wavelength of Coast)))/Wave Number for Waves in Coast)

Can the Water Depth given Energy Dissipation Rate per unit Surface Area due to Wave Breaking be negative?

Yes, the Water Depth given Energy Dissipation Rate per unit Surface Area due to Wave Breaking, measured in Length can be negative.

Which unit is used to measure Water Depth given Energy Dissipation Rate per unit Surface Area due to Wave Breaking?

Water Depth given Energy Dissipation Rate per unit Surface Area due to Wave Breaking is usually measured using the Meter[m] for Length. Millimeter[m], Kilometer[m], Decimeter[m] are the few other units in which Water Depth given Energy Dissipation Rate per unit Surface Area due to Wave Breaking can be measured.

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