Equations for internal referencing

Equations for internal referencing#

TS-length relationship

\[ \textit{TS} = m\log_{10}L+b \]

See Equation 1.6 for more details.

Relationship between volumetric backscatter and animal number density (animals m-3)

\[ s_\text{v} = \rho_\text{v} \left< \sigma_\text{bs} \right> \]

See Equation 1.10 for more details.

Vertical integration of volumetric backscatter in the water column

\[ s_\text{a} = \int\limits_{z_1}^{z_2} s_\text{v} dz = s_\text{v} H \]

See Equation 1.11 for more details.

Vertical integration of volumetric backscatter in the water column

\[ \rho_\text{a}(x) = \frac{s_\text{a}(x)}{\left< \sigma_\text{bs} \right>} \]

See Equation 1.13 for more details.

Areal number density (animals nmi-2)

\[ \rho_\text{A} = \frac{s_\text{A}}{4 \pi \left< \sigma_\text{bs} \right>} = \frac{s_\text{A}}{\sigma_\text{sp}} \]

See Equation 1.15 for more details.

Average animal weights

\[ \left< w \right> = \frac{\sum\limits_{j=1}^N w_j}{N} \]

See Equation 2.1b for more details.

Discretized length-weight distributions

\[ \left< w \right> = \tilde{\mathbf{L}}^{\mathsf{T}} \mathbf{w} \]

See Equation 2.2b for more details.

Normalized length frequency distribution

\[\begin{align*} \tilde{\mathbf{L}} = \left[ \begin{split} \tilde{L}&_1 \\ \tilde{L}&_2 \\ \tilde{L}&_3 \\ \vdots& \end{split} \right]. \end{align*}\]

See Equation 2.3 for more details.

Weight-length distribution

\[\begin{align*} \mathbf{w} = \left[ \begin{split} w&_1 \\ w&_2 \\ w&_3 \\ \vdots& \end{split} \right]. \end{align*}\]

See Equation 2.5 for more details.

Weight-length log-linear relationship

\[ \log_{10}(\hat{w}) = \log_{10}(\hat{a}) + \hat{b} \log_{10}(L) \]

See Equation 2.6 for more details.

Weight estimate for length bin \(\ell\)

\[ w_\ell = \left[ 10^{\hat{a}} {(L_{\ell}^{*})}^{\hat{b}} \right] L_\ell \]

See Equation 2.6 for more details.

Areal biomass density (kg nmi-2) for each sex

\[ \rho_{B; s} = \rho^i_{B; s}(x,y) = \rho_A(x,y) (\tilde{\mathbf{L}}^i_s)^\top \mathbf{w}^i_s \]

See Equation 2.9 for more details.

Sex-specific normalized length frequency distribution

\[\begin{align*} \tilde{\mathbf{L}}^i_s &= \left[ \begin{split} \tilde{L}&^i_{s,1} \\ \tilde{L}&^i_{s,2} \\ \tilde{L}&^i_{s,3} \\ &\vdots \end{split} \right], \\[2ex] \sum_{s,\ell} \tilde{L}^i_{s,\ell} &= 1. \end{align*}\]

See Equation 2.10 for more details.

Normalized weight-length distribution for each sex

\[\begin{align*} \tilde{\mathbf{w}}^i_s = \left[ \begin{split} \tilde{w}&^i_{s,1} \\ \tilde{w}&^i_{s,2} \\ \tilde{w}&^i_{s,3} \\ &\vdots \end{split} \right]. \end{align*}\]

See Equation 2.11 for more details.

Normalized weight-length distribution bins

\[\begin{align*} \tilde{w}^i_{s,\ell} &= \frac{\mathbf{w}^i_s}{\sum\limits_{\ell} w^i_{s,\ell}} = \frac{w^i_\ell}{\sum\limits_{s,\ell} w^i_{s,\ell}}, \\[2ex] \sum\limits_{s,\ell} \tilde{w}^i_{s,\ell} &= 1. \end{align*}\]

See Equation 2.12 for more details.

Transect-specific mean density

\[ \hat{z}^{\,t} = \frac{\sum\limits_{k \in t} z(x^k)}{d^t} \]

See Equation 2.15 for more details.

Distance-based transect weights

\[ \tau^t = \frac{d^t}{\frac{1}{n^i} \sum\limits_{t \in i} d^t} \]

See Equation 2.16 for more details.

Stratum-specific mean density

\[ \hat{z}^{i} = \frac{1}{n^i} \sum\limits_{t \in i} \tau^t \hat{z}^{t} \]

See Equation 2.17 for more details.

Survey mean density

\[ \hat{z} = \frac{\sum\limits_{i} A_i \hat{z}^i}{\sum\limits_i A_i} \]

See Equation 2.18 for more details.

Within-stratum survey variance

\[ \mathbb{V}(\hat{z}^i) = \frac{\sum\limits_{t \in i} \tau^t (\hat{z}^t - \hat{z}^i)^2}{n^i(n^i - 1)} \]

See Equation 2.19 for more details.

Area-weighted survey variance

\[ \mathbb{V}(\hat{z}) = \frac{\sum\limits_i (A^i)^2\, \mathbb{V}(\hat{z}^i)}{\left( \sum\limits_i A^i \right)^2} \]

See Equation 2.20 for more details.

Random field (or spatial process)

\[ \{ Z(\mathbf{x}) : \mathbf{x} \in D \subset \mathbb{R}^d\} \]

See Equation 3.1 for more details.

Semivariance

\[ \gamma(h) = \mathbb{C}(0) - \mathbb{C}(h) \]

See Equation 3.4 for more details.

Empirical semivariogram

\[ \hat{\gamma}(h) = \frac{1}{2N(h)} \sum_{i<j:\; h_{ij}\approx h} \bigl(z(\mathbf{x}_j)-z(\mathbf{x}_i)\bigr)^2 \]

See Equation 3.7 for more details.

Kriging linear predictor

\[ \mathbf{z}^*(\mathbf{u}) = \sum_{b=1}^n \lambda_b(\mathbf{u}) z(\mathbf{u}_b) + \left[ 1 - \sum_{b=1}^n \lambda_b(\mathbf{u}) \right] \mathbf{m} \]

See Equation 3.19 for more details.

Ordinary Kriging linear predictor

\[ \mathbf{z}^*(\mathbf{u}) = \sum_{b=1}^n \lambda_b(\mathbf{u}) z(\mathbf{u}_b) + \left[ 1 - \sum_{b=1}^n \lambda_b(\mathbf{u}) \right] \mathbf{m} \]

See Equation 3.19 for more details.

Minimized kriging estimate variance

\[ \min \sigma_E^2(\mathbf{u}) = \min \mathbb{V}[\mathbf{z}^*(\mathbf{u}) - Z(\mathbf{u})] \]

See Equation 3.22 for more details.

Kriging linear matrix

\[\begin{equation*} \mathbf{\Gamma}_{n \times n} = \begin{bmatrix}     \gamma(\mathbf{u}_1 - \mathbf{u}_1) & \gamma(\mathbf{u}_1 - \mathbf{u}_2) & \cdots & \gamma(\mathbf{u}_1 - \mathbf{u}_n) \\     \gamma(\mathbf{u}_2 - \mathbf{u}_1) & \gamma(\mathbf{u}_2 - \mathbf{u}_2) & \cdots & \gamma(\mathbf{u}_2 - \mathbf{u}_n) \\     \vdots & \vdots & \ddots & \vdots \\     \gamma(\mathbf{u}_n - \mathbf{u}_1) & \gamma(\mathbf{u}_n - \mathbf{u}_2) & \cdots & \gamma(\mathbf{u}_n - \mathbf{u}_n) \end{bmatrix} \end{equation*}\]

See Equation 3.23 for more details.

Kriging estimation variance

\[ \sigma_E^2(\mathbf{u}) = - \sum_{i=1}^n \sum_{j=1}^n \lambda_i \lambda_j \gamma(\mathbf{u}_i - \mathbf{u}_j) + 2 \sum_{j=1}^n \lambda_i \gamma(\mathbf{u}_i - \mathbf{u}) \]

See Equation 3.24a for more details.

Simplified Lagrangian multiplier

\[ \sum_{j=1}^n \lambda_j \gamma(\mathbf{u}_j - \mathbf{u}_b) + \mu = \gamma(\mathbf{u}_b - \mathbf{u}) \]

See Equation 3.26b for more details.

Kriging optimization constraint

\[ \frac{\partial \mathcal{L}}{\partial \mu} = 2 \left(1 - \sum_{j=1}^n \lambda_j\right) = 0 \]

See Equation 3.26c for more details.

Kriging system of equations required for solving for \(\lambda\)

\[\begin{equation*} \begin{cases} \sum\limits_{j=1}^n \lambda_j(\mathbf{u})\gamma(\mathbf{u}_j - \mathbf{u}_i) + \mu = \gamma(\mathbf{u}_i - \mathbf{u}) & \text{for } i = 1, \ldots, n \\ \sum\limits_{j=1}^n \lambda_j(\mathbf{u}) = 1 \end{cases} \tag{3.27} \end{equation*}\]

See Equation 3.27 for more details.