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Straight-Line Distance given Time required for Waves Crossing Fetch under Wind Velocity Formula

GoStraight-Line Distance over which Wind Blows Formula

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Straight Line Distance over which Wind Blows is defined as total stretch of wind motion in a straight line influencing other parameters of the wave. Check FAQs

X = {(\frac{t x,u \cdot U^{0.34} \cdot {[g]}^{0.33}}{77.23})}^{\frac{1}{0.67}}

X - Straight Line Distance over which Wind Blows?t_x,u - Time required for Waves crossing Fetch?U - Wind Speed?[g] - Gravitational acceleration on Earth?

Straight-Line Distance given Time required for Waves Crossing Fetch under Wind Velocity Example

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Here is how the Straight-Line Distance given Time required for Waves Crossing Fetch under Wind Velocity equation looks like with Values.

Here is how the Straight-Line Distance given Time required for Waves Crossing Fetch under Wind Velocity equation looks like with Units.

Here is how the Straight-Line Distance given Time required for Waves Crossing Fetch under Wind Velocity equation looks like.

15.1171 = {(\frac{140 \cdot 4^{0.34} \cdot {9.8066}^{0.33}}{77.23})}^{\frac{1}{0.67}}

15.1171m = {(\frac{140s \cdot {4m/s}^{0.34} \cdot {9.8066m/s²}^{0.33}}{77.23})}^{\frac{1}{0.67}}

15.1171 = {(\frac{140 \cdot 4^{0.34} \cdot {9.8066}^{0.33}}{77.23})}^{\frac{1}{0.67}}

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Straight-Line Distance given Time required for Waves Crossing Fetch under Wind Velocity Solution

Follow our step by step solution on how to calculate Straight-Line Distance given Time required for Waves Crossing Fetch under Wind Velocity?

FIRST Step Consider the formula

X = {(\frac{t x,u \cdot U^{0.34} \cdot {[g]}^{0.33}}{77.23})}^{\frac{1}{0.67}}

Next Step Substitute values of Variables

∴

X = {(\frac{140s \cdot {4m/s}^{0.34} \cdot {[g]}^{0.33}}{77.23})}^{\frac{1}{0.67}}

Next Step Substitute values of Constants

∴

X = {(\frac{140s \cdot {4m/s}^{0.34} \cdot {9.8066m/s²}^{0.33}}{77.23})}^{\frac{1}{0.67}}

Next Step Prepare to Evaluate

∴

X = {(\frac{140 \cdot 4^{0.34} \cdot {9.8066}^{0.33}}{77.23})}^{\frac{1}{0.67}}

Next Step Evaluate

∴

X = 15.1171174168249m

LAST Step Rounding Answer

∴

X = 15.1171m

Straight-Line Distance given Time required for Waves Crossing Fetch under Wind Velocity Formula Elements

Variables

Constants

Straight Line Distance over which Wind Blows

Straight Line Distance over which Wind Blows is defined as total stretch of wind motion in a straight line influencing other parameters of the wave.

Symbol: X

Measurement: LengthUnit: m

Note: Value can be positive or negative.

Formulas to find Straight Line Distance over which Wind Blows

Time required for Waves crossing Fetch

Time required for Waves crossing Fetch under Wind Velocity to become Fetch Limited.

Symbol: t_x,u

Measurement: TimeUnit: s

Note: Value can be positive or negative.

Formulas to find Time required for Waves crossing Fetch

Wind Speed

Wind Speed is a fundamental atmospheric quantity caused by air moving from high to low pressure, usually due to changes in temperature.

Symbol: U

Measurement: SpeedUnit: m/s

Note: Value should be greater than 0.

Formulas to find Wind Speed

Gravitational acceleration on Earth

Gravitational acceleration on Earth means that the velocity of an object in free fall will increase by 9.8 m/s2 every second.

Symbol: [g]

Value: 9.80665 m/s²

Other Formulas to find Straight Line Distance over which Wind Blows

Go Straight-Line Distance over which Wind Blows

X = (\frac{{V f}^{2}}{[g]}) \cdot 5.23 \cdot 10^{- 3} \cdot {([g] \cdot \frac{t}{V f})}^{\frac{3}{2}}

Other formulas in Wave Hindcasting and Forecasting category

Go Spectral Energy Density

E (f) = \frac{λ \cdot ({[g]}^{2}) \cdot (f^{- 5})}{{(2 \cdot π)}^{4}}

Go Spectral Energy Density or Classical Moskowitz Spectrum

E (f) = (\frac{λ \cdot ({[g]}^{2}) \cdot (f^{- 5})}{{(2 \cdot π)}^{4}}) \cdot \exp (0.74 \cdot {(\frac{f}{f u})}^{- 4})

Go Time required for Waves Crossing Fetch under Wind Velocity to become Fetch Limited

t x,u = 77.23 \cdot (\frac{X^{0.67}}{U^{0.34} \cdot {[g]}^{0.33}})

Go Wind Speed given Time required for Waves crossing Fetch under Wind Velocity

U = {(\frac{77.23 \cdot X^{0.67}}{t x,u \cdot {[g]}^{0.33}})}^{\frac{1}{0.34}}

How to Evaluate Straight-Line Distance given Time required for Waves Crossing Fetch under Wind Velocity?

Straight-Line Distance given Time required for Waves Crossing Fetch under Wind Velocity evaluator uses Straight Line Distance over which Wind Blows = ((Time required for Waves crossing Fetch*Wind Speed^0.34*[g]^0.33)/77.23)^(1/0.67) to evaluate the Straight Line Distance over which Wind Blows, The Straight-Line Distance given Time required for Waves Crossing Fetch under Wind Velocity formula is defined as the total stretch in a straight line for the waves to become fetch limited. Straight Line Distance over which Wind Blows is denoted by X symbol.

How to evaluate Straight-Line Distance given Time required for Waves Crossing Fetch under Wind Velocity using this online evaluator? To use this online evaluator for Straight-Line Distance given Time required for Waves Crossing Fetch under Wind Velocity, enter Time required for Waves crossing Fetch (t_x,u) & Wind Speed (U) and hit the calculate button.

FAQs on Straight-Line Distance given Time required for Waves Crossing Fetch under Wind Velocity

What is the formula to find Straight-Line Distance given Time required for Waves Crossing Fetch under Wind Velocity?

The formula of Straight-Line Distance given Time required for Waves Crossing Fetch under Wind Velocity is expressed as Straight Line Distance over which Wind Blows = ((Time required for Waves crossing Fetch*Wind Speed^0.34*[g]^0.33)/77.23)^(1/0.67). Here is an example- 15.11712 = ((140*4^0.34*[g]^0.33)/77.23)^(1/0.67).

How to calculate Straight-Line Distance given Time required for Waves Crossing Fetch under Wind Velocity?

With Time required for Waves crossing Fetch (t_x,u) & Wind Speed (U) we can find Straight-Line Distance given Time required for Waves Crossing Fetch under Wind Velocity using the formula - Straight Line Distance over which Wind Blows = ((Time required for Waves crossing Fetch*Wind Speed^0.34*[g]^0.33)/77.23)^(1/0.67). This formula also uses Gravitational acceleration on Earth constant(s).

What are the other ways to Calculate Straight Line Distance over which Wind Blows?

Here are the different ways to Calculate Straight Line Distance over which Wind Blows-

Straight Line Distance over which Wind Blows=(Friction Velocity^2/[g])*5.23*10^-3*([g]*Wind Duration/Friction Velocity)^(3/2)

Can the Straight-Line Distance given Time required for Waves Crossing Fetch under Wind Velocity be negative?

Yes, the Straight-Line Distance given Time required for Waves Crossing Fetch under Wind Velocity, measured in Length can be negative.

Which unit is used to measure Straight-Line Distance given Time required for Waves Crossing Fetch under Wind Velocity?

Straight-Line Distance given Time required for Waves Crossing Fetch under Wind Velocity is usually measured using the Meter[m] for Length. Millimeter[m], Kilometer[m], Decimeter[m] are the few other units in which Straight-Line Distance given Time required for Waves Crossing Fetch under Wind Velocity can be measured.

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