Maximum River Density given Relative Density Solution

STEP 0: Pre-Calculation Summary
Formula Used
Maximum River Density = (Broad Sense Heritability*Average River Density)+Minimum River Density
ρmax = (H2*ρ')+ρmin
This formula uses 4 Variables
Variables Used
Maximum River Density - Maximum River Density is a measurement of the sum of the highest channel lengths per unit area.
Broad Sense Heritability - Broad Sense Heritability is reflects all the genetic contributions to a population's phenotypic variance including additive, dominant, and epistatic.
Average River Density - (Measured in Kilogram per Cubic Meter) - Average River Density over one tide period. Drainage density relates to the efficiency by which water is carried over the landscape.
Minimum River Density - Minimum River Density is a measurement of the sum of the lowest channel lengths per unit area.
STEP 1: Convert Input(s) to Base Unit
Broad Sense Heritability: 11 --> No Conversion Required
Average River Density: 8 Kilogram per Cubic Meter --> 8 Kilogram per Cubic Meter No Conversion Required
Minimum River Density: 12 --> No Conversion Required
STEP 2: Evaluate Formula
Substituting Input Values in Formula
ρmax = (H2*ρ')+ρmin --> (11*8)+12
Evaluating ... ...
ρmax = 100
STEP 3: Convert Result to Output's Unit
100 --> No Conversion Required
FINAL ANSWER
100 <-- Maximum River Density
(Calculation completed in 00.004 seconds)

Credits

Created by Mithila Muthamma PA
Coorg Institute of Technology (CIT), Coorg
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National Institute of Technology Karnataka (NITK), Surathkal
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23 Density Currents in Harbors Calculators

Cross-Sectional Area of Entrance given Water Volume exchanged during entire Tide Period
Go Cross Sectional Area of Entrance = Total Water Volume/(Coefficient for Harbors*sqrt(Broad Sense Heritability*Average Harbor Depth))
Total Water Volume Exchanged during entire Tide Period
Go Total Water Volume = Coefficient for Harbors*Cross Sectional Area of Entrance*sqrt(Broad Sense Heritability*Average Harbor Depth)
Average Depth of Harbor for Water Volume Exchanged during Entire Tide Period
Go Average Harbor Depth = ((Total Water Volume/Coefficient for Harbors*Cross Sectional Area of Entrance)^(1/2 ))/Broad Sense Heritability
Total Harbor Volume based upon Depth given difference between High and Low Tide Levels
Go Total Harbor Volume = Tidal Prism Filling Bay/(Difference between High and Low Tide level/Average Harbor Depth)
Tidal Prism of Harbor Basin given Difference between High and Low Tide Levels
Go Tidal Prism Filling Bay = Total Harbor Volume*(Difference between High and Low Tide level/Average Harbor Depth)
Difference between High and Low Tide Levels given Tidal Prism of Harbor Basin
Go Difference between High and Low Tide level = (Tidal Prism Filling Bay/Total Harbor Volume)*Average Harbor Depth
Velocity in Dry Bed Curve
Go Velocity in Dry Bed Curve = 0.45*sqrt(Broad Sense Heritability*[g]*Water Depth)
Average Harbor Depth
Go Average Harbor Depth = (Difference between High and Low Tide level*Total Harbor Volume)/Tidal Prism Filling Bay
Minimum River Density given Relative Density
Go Minimum River Density = -((Broad Sense Heritability*Average River Density)-Maximum River Density)
Average River Density over one Tide Period given Relative Density
Go Average River Density = (Maximum River Density-Minimum River Density)/Broad Sense Heritability
Maximum River Density given Relative Density
Go Maximum River Density = (Broad Sense Heritability*Average River Density)+Minimum River Density
Relative Density given River Density
Go Broad Sense Heritability = (Maximum River Density-Minimum River Density)/Average River Density
Water Depth given Velocity in Dry Bed Curve
Go Water Depth = ((Velocity in Dry Bed Curve/0.45)^2)/(Broad Sense Heritability*[g])
Relative Density given Velocity in Dry Bed Curve
Go Broad Sense Heritability = Velocity in Dry Bed Curve^2/(0.45*[g]*Water Depth)
Difference between High and Low Tide Levels given Portion caused by Filling
Go Difference between High and Low Tide level = Average Harbor Depth*Portion caused by Filling
Portion caused by Filling given Average Harbor Depth
Go Portion caused by Filling = Difference between High and Low Tide level/Average Harbor Depth
Average Harbor Depth given Portion caused by Filling
Go Average Harbor Depth = Difference between High and Low Tide level/Portion caused by Filling
Portion caused by Filling Evaluated by Comparing Tidal Prism of Harbor to Total Harbor Volume
Go Portion caused by Filling = Tidal Prism Filling Bay/Total Harbor Volume
Total Harbor Volume based upon Depth
Go Total Harbor Volume = Tidal Prism Filling Bay/Portion caused by Filling
Tidal Prism of Harbor Basin
Go Tidal Prism Filling Bay = Portion caused by Filling*Total Harbor Volume
Portion caused by Filling given Ratio of Water Volume Entering Harbor per Tide
Go Portion caused by Filling = Ratio of Water Volume-Density Influence
Density Influence given Ratio of Water Volume entering Harbor per Tide
Go Density Influence = Ratio of Water Volume-Portion caused by Filling
Ratio of Water Volume entering Harbor per Tide to Harbor Volume
Go Ratio of Water Volume = Portion caused by Filling+Density Influence

Maximum River Density given Relative Density Formula

Maximum River Density = (Broad Sense Heritability*Average River Density)+Minimum River Density
ρmax = (H2*ρ')+ρmin

What is Density Current?

Density current, any current in either a liquid or a gas that is kept in motion by the force of gravity acting on differences in density. A density difference can exist between two fluids because of a difference in temperature, salinity, or concentration of suspended sediment.

How to Calculate Maximum River Density given Relative Density?

Maximum River Density given Relative Density calculator uses Maximum River Density = (Broad Sense Heritability*Average River Density)+Minimum River Density to calculate the Maximum River Density, The Maximum River Density given Relative Density formula is defined as it is a measure of the length of the stream channel per unit area of a drainage basin. Maximum River Density is denoted by ρmax symbol.

How to calculate Maximum River Density given Relative Density using this online calculator? To use this online calculator for Maximum River Density given Relative Density, enter Broad Sense Heritability (H2), Average River Density (ρ') & Minimum River Density min) and hit the calculate button. Here is how the Maximum River Density given Relative Density calculation can be explained with given input values -> 100 = (11*8)+12.

FAQ

What is Maximum River Density given Relative Density?
The Maximum River Density given Relative Density formula is defined as it is a measure of the length of the stream channel per unit area of a drainage basin and is represented as ρmax = (H2*ρ')+ρmin or Maximum River Density = (Broad Sense Heritability*Average River Density)+Minimum River Density. Broad Sense Heritability is reflects all the genetic contributions to a population's phenotypic variance including additive, dominant, and epistatic, Average River Density over one tide period. Drainage density relates to the efficiency by which water is carried over the landscape & Minimum River Density is a measurement of the sum of the lowest channel lengths per unit area.
How to calculate Maximum River Density given Relative Density?
The Maximum River Density given Relative Density formula is defined as it is a measure of the length of the stream channel per unit area of a drainage basin is calculated using Maximum River Density = (Broad Sense Heritability*Average River Density)+Minimum River Density. To calculate Maximum River Density given Relative Density, you need Broad Sense Heritability (H2), Average River Density (ρ') & Minimum River Density min). With our tool, you need to enter the respective value for Broad Sense Heritability, Average River Density & Minimum River Density 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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