Standing Wave Height given Maximum Horizontal Velocity at Node Calculator

✖Maximum Horizontal Velocity at a Node refers to the highest velocity component in the horizontal direction at that particular node in a fluid flow simulation.ⓘ Maximum Horizontal Velocity at a Node [V_max]			+10% -10%
✖Depth of Water is the depth as measured from the water level to the bottom of the considered water body.ⓘ Depth of Water [D_w]			+10% -10%

✖Standing Wave Height of Ocean results when two equal waves are going in opposite direction.ⓘ Standing Wave Height given Maximum Horizontal Velocity at Node [H_w]

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Formula

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Standing Wave Height given Maximum Horizontal Velocity at Node

Formula

H w = (\frac{V max}{\sqrt{\frac{[g]}{D w}}}) \cdot 2

Example

1.01 m = (\frac{554.5413 m/h}{\sqrt{\frac{[g]}{105.4 m}}}) \cdot 2

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Standing Wave Height given Maximum Horizontal Velocity at Node Solution

STEP 0: Pre-Calculation Summary

Formula Used

Standing Wave Height of Ocean = (Maximum Horizontal Velocity at a Node/sqrt([g]/Depth of Water))*2
H_w = (V_max/sqrt([g]/D_w))*2
This formula uses 1 Constants, 1 Functions, 3 Variables

Constants Used

[g] - Gravitational acceleration on Earth Value Taken As 9.80665

Functions Used

sqrt - A square root function is a function that takes a non-negative number as an input and returns the square root of the given input number., sqrt(Number)

Variables Used

Standing Wave Height of Ocean - (Measured in Meter) - Standing Wave Height of Ocean results when two equal waves are going in opposite direction.
Maximum Horizontal Velocity at a Node - (Measured in Meter per Second) - Maximum Horizontal Velocity at a Node refers to the highest velocity component in the horizontal direction at that particular node in a fluid flow simulation.
Depth of Water - (Measured in Meter) - Depth of Water is the depth as measured from the water level to the bottom of the considered water body.

STEP 1: Convert Input(s) to Base Unit

Maximum Horizontal Velocity at a Node: 554.5413 Meter per Hour --> 0.15403925 Meter per Second (Check conversion here)
Depth of Water: 105.4 Meter --> 105.4 Meter No Conversion Required

STEP 2: Evaluate Formula

Substituting Input Values in Formula

H_w = (V_max/sqrt([g]/D_w))*2 --> (0.15403925/sqrt([g]/105.4))*2

Evaluating ... ...

H_w = 1.00999996501168

STEP 3: Convert Result to Output's Unit

1.00999996501168 Meter --> No Conversion Required

FINAL ANSWER

1.00999996501168 ≈ 1.01 Meter <-- Standing Wave Height of Ocean

(Calculation completed in 00.020 seconds)

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< Important Formulas of Harbor Oscillation Calculators

Resonant Period for Helmholtz Mode

Go Resonant Period for Helmholtz Mode = (2*pi)*sqrt((Channel Length (Helmholtz Mode)+Additional Length of the Channel)*Surface Area of Bay/([g]*Cross Sectional Area))

Standing Wave Height given Maximum Horizontal Velocity at Node

Go Standing Wave Height of Ocean = (Maximum Horizontal Velocity at a Node/sqrt([g]/Depth of Water))*2

Maximum Horizontal Velocity at Node

Go Maximum Horizontal Velocity at a Node = (Standing Wave Height of Ocean/2)*sqrt([g]/Depth of Water)

Water Depth given Maximum Horizontal Velocity at Node

Go Depth of Water = [g]/(Maximum Horizontal Velocity at a Node/(Standing Wave Height of Ocean/2))^2

Standing Wave Height given Maximum Horizontal Velocity at Node Formula

Standing Wave Height of Ocean = (Maximum Horizontal Velocity at a Node/sqrt([g]/Depth of Water))*2
H_w = (V_max/sqrt([g]/D_w))*2

What are Closed Basins?

Enclosed basins can experience oscillations due to a variety of causes. Lake oscillations are usually the result of a sudden change, or a series of intermittent-periodic changes, in atmospheric pressure or wind velocity. Oscillations in canals can be initiated by suddenly adding or subtracting large quantities of water. Harbor oscillations are usually initiated by forcing through the entrance; hence, they deviate from a true closed basin. Local seismic activity can also create oscillations in an enclosed basin.

What are Open Basins?

Open Basins are Exorheic, or open lakes drain into a river, or other body of water that ultimately drains into the ocean.

How to Calculate Standing Wave Height given Maximum Horizontal Velocity at Node?

Standing Wave Height given Maximum Horizontal Velocity at Node calculator uses Standing Wave Height of Ocean = (Maximum Horizontal Velocity at a Node/sqrt([g]/Depth of Water))*2 to calculate the Standing Wave Height of Ocean, The Standing Wave Height given Maximum Horizontal Velocity at Node is defined as the relationship between the vertical amplitude of the standing wave and the speed of water flow at a stationary point within the wave. Standing Wave Height of Ocean is denoted by H_w symbol.

How to calculate Standing Wave Height given Maximum Horizontal Velocity at Node using this online calculator? To use this online calculator for Standing Wave Height given Maximum Horizontal Velocity at Node, enter Maximum Horizontal Velocity at a Node (V_max) & Depth of Water (D_w) and hit the calculate button. Here is how the Standing Wave Height given Maximum Horizontal Velocity at Node calculation can be explained with given input values -> 1.01 = (0.15403925/sqrt([g]/105.4))*2.

FAQ

What is Standing Wave Height given Maximum Horizontal Velocity at Node?

The Standing Wave Height given Maximum Horizontal Velocity at Node is defined as the relationship between the vertical amplitude of the standing wave and the speed of water flow at a stationary point within the wave and is represented as H_w = (V_max/sqrt([g]/D_w))*2 or Standing Wave Height of Ocean = (Maximum Horizontal Velocity at a Node/sqrt([g]/Depth of Water))*2. Maximum Horizontal Velocity at a Node refers to the highest velocity component in the horizontal direction at that particular node in a fluid flow simulation & Depth of Water is the depth as measured from the water level to the bottom of the considered water body.

How to calculate Standing Wave Height given Maximum Horizontal Velocity at Node?

The Standing Wave Height given Maximum Horizontal Velocity at Node is defined as the relationship between the vertical amplitude of the standing wave and the speed of water flow at a stationary point within the wave is calculated using Standing Wave Height of Ocean = (Maximum Horizontal Velocity at a Node/sqrt([g]/Depth of Water))*2. To calculate Standing Wave Height given Maximum Horizontal Velocity at Node, you need Maximum Horizontal Velocity at a Node (V_max) & Depth of Water (D_w). With our tool, you need to enter the respective value for Maximum Horizontal Velocity at a Node & Depth of Water 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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