Nomenclature: Difference between revisions

Revision as of 23:49, 22 April 2021

Frame of reference

Define frame of reference, and notation. Use u,v,w and x,y, and z?
Dumping a sketch would be useful

Reynold's Decomposition

Variable names for Decomposition of total, mean, turbulent and waves.

Background (total) velocity

Parameter name	Symbol	Description	Standard long name	Units
EAST_VEL	$u$	zonal velocity	eastward_velocity	m s-1
NORTH_VEL	$v$	meridional velocity	northward_velocity	m s-1
UP_VEL	$W$	vertical velocity	upward_velocity	m s-1
ERROR_VEL	$u$	error velocity	error_velocity	m s-1
U_VEL	$U$	velocity parellel to mean flow	meanflow_velocity	m s-1
V_VEL	$V$	velocity perpendicular to mean flow	crossflow_velocity	m s-1
Drop_Speed	$W_{d}$	Profiler fall speed	mean_drop_speed	m s-1
FlowPast_Speed	$U_{f} p$	Flow speed past sensor	mean_velocity_past_turbulence_sensor	m s-1
AlongBeam_Velocity	$b$	Along-beam velocity from acoustic Doppler sensor	observed_speed_along_an_acoustic_beam	m s-1

Turbulence properties

Parameter name	Symbol	Description	Standard long name	Eqn	Units
EPSI	$ε$	Turbulent kinetic energy dissipation	tke_dissipation		W/kg
RI	$R i$	Richardson number	richardson_number	$R i = \frac{N^{2}}{S^{2}}$
RI_F	$R i_{f}$	Flux gradient Richardson number	flux_grad_richardson_number	$\frac{B}{P}$ or Ivey & Immerger? Karan et cie
Krho	$κ_{ρ}$	Turbulent diffusivity	turbulent_diffusivity	$κ = Γ ϵ N^{- 2}$	m $2$ s $- 1$

Fluid properties and background gradients for turbulence calculations

Parameter Name	Symbol	Description	Standard long name	Eqn	Units
S	$S$	Background velocity shear	background_velocity_shear	$S = \frac{\partial \| U \|}{\partial z}$	s $- 1$
KVISC35	$ν$	Kinematic viscosity of water for seawater at 35 and 20 $o$ C	seawater_kinematic_viscosity_at_35psu	$1 \times 1 0^{- 6}$	m2/s
N	$N$	Background stratification, i.e buoyancy frequency	background_buoyancy_frequency	$N = \sqrt{\frac{- g}{\bar{ρ}} \frac{\partial \bar{ρ}}{\partial z}}$	rad/s

Theoretical Length and Time Scales

Parameter	Symbol	Description	Standard long name	Eqn	Units
T_N	$τ_{N}$	Buoyancy timescale	buoyancy_time_scale	$τ_{N} = \frac{2 π}{N}$	s
L_E	$L_{E}$	Ellison length scale (limit of vertical displacement without irreversible mixing)	Eliison_lenght_scale	$L_{E} = \frac{⟨ ρ'^{2} ⟩^{1 / 2}}{\partial \overline{ρ} / \partial z}$	m
L_RHO	$L_{ρ}$	Density length scale	density_length_scale	$L_{ρ}$	m
L_S	$L_{S}$	Corssin length scale	Corssin_shear_length_scale	$L_{S} = \sqrt{ϵ / S^{3}}$	m
L_K	$η$	Kolmogorov length scale (smallest overturns)	Kolmogorov_length_scale	$η = {(\frac{ν^{3}}{ϵ})}^{1 / 4} = \frac{1}{2 π {\hat{k}}_{K}}$	m
L_O	$L_{o}$	Ozmidov length scale, measure of largest overturns in a stratified fluid	Ozmidov_stratification_length_scale	$L_{o} = {(\frac{ϵ}{N^{3}})}^{1 / 2}$	m
L_T	$L_{T}$	Thorp length scale	Thorpe_stratification_length_scale	$L_{T}$	m

Turbulence Spectrum

Taylor's Frozen Turbulence for converting temporal to spatial measurements $({\bar{u}}_{1} \frac{\partial}{\partial x} = \frac{\partial}{\partial t})$

Missing the y-axi variable. CEB proposes:
- $Ψ_{v a r i a b l e}$ for model/theoretical spectrum of variable e.g., du/dx or u
- $Φ_{v a r i a b l e}$ for observed spectrum of variable e.g., du/dx or u
Lowest frequency and wavenumber resolvable

Symbol	Description	Eqn	Units
$Δ t$	Sampling interval	$\frac{1}{f_{s}}$	s
$Δ s$	Sampling volume dimension		m
$f$	Frequency	$\frac{ω}{2 π}$	Hz
$f_{n}$	Nyquist frequency	$f_{n} = 0.5 f_{s}$	Hz
$f_{s}$	Sampling frequency	$f_{s} = \frac{1}{Δ t}$	Hz
$k$	Wavenumbers (angular)	$k = \frac{f}{\bar{u}} = 2 π \hat{k}$	rad/m
$\hat{k}$	Wavenumbers	$\hat{k} = \frac{k}{2 π}$	cpm
${\hat{k}}_{Δ}$	Nyquist wavenumber, based on sampling volume's size $Δ l$	${\hat{k}}_{Δ} = \frac{0.5}{Δ l}$	cpm
${\hat{k}}_{n}$	Nyquist wavenumber, via Taylor's hypothesis (temporal measurements)	${\hat{k}}_{n} = \frac{f_{n}}{u}$	cpm
$ω$	Angular frequency	$2 π f$	rad/s

Supplementary Data required for computing Turbulence

Channel	Shear Probes	ADCP	ADVs
Ax	x	x	x
Ay	x	x	x
Az	x	x	x

@@ Line 20: / Line 20: @@
 |-
 |EAST_VEL
-| <math>u</math>
+| <math> u </math>
 | zonal velocity
 | eastward_velocity
@@ Line 62: / Line 62: @@
 |-
 |FlowPast_Speed
-| <math> U_p </math>
+| <math> U_fp </math>
 | Flow speed past sensor
 | mean_velocity_past_turbulence_sensor
 | m s-1
 |-
-|AlongBeam_Speed
+|AlongBeam_Velocity
 | <math> b </math>
 | Along-beam velocity from acoustic Doppler sensor
@@ Line 75: / Line 75: @@
 |}
-== Computed Turbulence Properties ==
+== Turbulence properties ==
 {| class="wikitable"
 |- Style="font-weight:bold; "
@@ Line 146: / Line 146: @@
 |}
-== Theoretical Scales ==
+== Theoretical Length and Time Scales ==
-=== Length L ===
-Here we use the variable <math>L_x</math> to designate all length scales, with subscript <math>x</math>. If the variable is a person (e.g., Ozmidov), use capital O.
 {| class="wikitable"
@@ Line 160: / Line 156: @@
 ! Eqn
 ! Units
+|-
+| T_N
+| <math>\tau_N</math>
+| Buoyancy timescale
+| buoyancy_time_scale
+| <math> \tau_N = \frac{2\pi}{N}</math>
+| s
 |-
 | L_E
@@ Line 169: / Line 172: @@
 |-
 | L_RHO
-| <math> L_\rho </math>
+| <math> L_\rho</math>
 | Density length scale
 | density_length_scale
@@ Line 183: / Line 186: @@
 |-
 | L_K
-| <math>L_K</math>
+| <math>\eta</math>
 | Kolmogorov length scale (smallest overturns)
 | Kolmogorov_length_scale
@@ Line 190: / Line 193: @@
 |-
 | L_O
-| <math>L_O</math>
+| <math>L_o</math>
 | Ozmidov length scale, measure of largest overturns in a stratified fluid
 | Ozmidov_stratification_length_scale
-| <math>L_O=\left(\frac{\epsilon}{N^3}\right)^{1/2}</math>
+| <math>L_o=\left(\frac{\epsilon}{N^3}\right)^{1/2}</math>
 | m
 |-
@@ Line 202: / Line 205: @@
 | <math>L_T</math>
 | m
-|-
-|}
-=== Time Scales ===
-{| class="wikitable"
-|- Style="font-weight:bold; "
-! Parameter
-! Symbol
-! Description
-! Standard long name
-! Eqn
-! Units
-|-
-| T_N
-| <math>\tau_N</math>
-| Buoyancy timescale
-| buoyancy_time_scale
-| <math> \tau_N = \frac{2\pi}{N}</math>
-| s
 |-
 |}
@@ Line 230: / Line 214: @@
-* Missing the y-axi variable
+* Missing the y-axi variable. CEB proposes:
 ** <math>\Psi_{variable}</math> for model/theoretical spectrum of variable e.g., du/dx or u
 ** <math>\Phi_{variable}</math> for observed spectrum of variable e.g., du/dx or u
@@ Line 257: / Line 241: @@
 | Hz
 |-
-| <math> f_N </math>
+| <math>f_n</math>
 | Nyquist frequency
-| <math>f_N = 0.5f_s</math>
+| <math>f_n=0.5f_s</math>
 | Hz
 |-
@@ Line 267: / Line 251: @@
 | Hz
 |-
-| <math>\hat{k}</math>
+| <math>k</math>
 | Wavenumbers (angular)
-| <math>\hat{k}=\frac{f}{\bar{u}}=2\pi k</math>
+| <math>k=\frac{f}{\bar{u}}=2\pi\hat{k}</math>
 | rad/m
 |-
-| <math>k</math>
+| <math>\hat{k}</math>
 | Wavenumbers
-| <math>k=\frac{\hat{k}}{2\pi}</math>
+| <math>\hat{k}=\frac{k}{2\pi}</math>
 | cpm
 |-
@@ Line 282: / Line 266: @@
 | cpm
 |-
-| <math>k_n</math>
+| <math>\hat{k}_n</math>
 | Nyquist wavenumber, via Taylor's hypothesis (temporal measurements)
-| <math>k_n=\frac{f_n}{u}</math>
+| <math>\hat{k}_n=\frac{f_n}{u}</math>
 | cpm
 |-

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Nomenclature: Difference between revisions

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Revision as of 23:49, 22 April 2021

Contents

Frame of reference

Reynold's Decomposition

Background (total) velocity

Turbulence properties

Fluid properties and background gradients for turbulence calculations

Theoretical Length and Time Scales

Turbulence Spectrum

Supplementary Data required for computing Turbulence

Navigation

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Anonymous

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Nomenclature: Difference between revisions

Revision as of 23:49, 22 April 2021

Frame of reference

Reynold's Decomposition

Background (total) velocity

Turbulence properties

Fluid properties and background gradients for turbulence calculations

Theoretical Length and Time Scales

Turbulence Spectrum

Supplementary Data required for computing Turbulence

Navigation

Wiki tools

Page tools