Differences
This shows you the differences between two versions of the page.
| en:manuel_reference:methode_micro:verif_habby [2021/12/02 10:36] – ylecoarer | en:manuel_reference:methode_micro:verif_habby [2021/12/02 10:48] () – ylecoarer | ||
|---|---|---|---|
| 6: | 6: | ||
| Here we will check the implementation of the The Instream Flow Incremental Methodology (IFIM) when using a 2D hydraulic model. | Here we will check the implementation of the The Instream Flow Incremental Methodology (IFIM) when using a 2D hydraulic model. | ||
| + | |||
| + | ==== HABBY habitat calculations ==== | ||
| The classic case consists of using a set of 3 habitat suitability curves for the variables water height, mean velocity and substrate (H,V,S) for a fish species and for a biological stage. | The classic case consists of using a set of 3 habitat suitability curves for the variables water height, mean velocity and substrate (H,V,S) for a fish species and for a biological stage. | ||
| 16: | 18: | ||
| (1b) \[HSI_i=(SI_H(H_i)\times SI_V(V_i)\times SI_S(S_i))^\frac{1}{3}\] | (1b) \[HSI_i=(SI_H(H_i)\times SI_V(V_i)\times SI_S(S_i))^\frac{1}{3}\] | ||
| (1c) \[HSI_i=\frac{SI_H(H_i)+ SI_V(V_i)+ SI_S(S_i)}{3}\] | (1c) \[HSI_i=\frac{SI_H(H_i)+ SI_V(V_i)+ SI_S(S_i)}{3}\] | ||
| + | |||
| + | In case the user decides to use only two variables for example (H,V), these equations are adapted in HABBY and become : | ||
| + | |||
| + | (1_a2) \[HSI_i=SI_H(H_i)\times SI_V(V_i)\] | ||
| + | (1_b2) \[HSI_i=(SI_H(H_i)\times SI_V(V_i))^\frac{1}{2}\] | ||
| + | (1_c2) \[HSI_i=\frac{SI_H(H_i)+ SI_V(V_i)}{2}\] | ||
| The logics (a) product, (b) geometric mean and (c) mean are respected. | The logics (a) product, (b) geometric mean and (c) mean are respected. | ||
| 23: | 31: | ||
| (1_biv) \[HSI_i=SI_{H, | (1_biv) \[HSI_i=SI_{H, | ||
| + | The weighted useable area WUA of the hydraulic model is obtained from equation (2) and the overall suitability index OSI from equation (3) | ||
| (2) \[WUA=\sum_{i=1}^M A_i\times HSI_i\] | (2) \[WUA=\sum_{i=1}^M A_i\times HSI_i\] | ||
| (3) \[OSI=\frac{WUA}{\sum_{i=1}^M A_i}\] | (3) \[OSI=\frac{WUA}{\sum_{i=1}^M A_i}\] | ||
| - | (4) \[{SI_{i, | ||
| - | The weighted useable area WUA of the hydraulic model is obtained from equation (2) and the overall suitability index OSI from equation (3) | + | |
| Note that in the particular case of a description of the substrate in percentages per $\mathit{S_k}$ classes and a calculation of habitat in % of substrate, the value of $\mathit{SI_S(S_i)}$ in equation (1) must be replaced by the formulation in equation (4). In this equation $\mathit{S_{i, | Note that in the particular case of a description of the substrate in percentages per $\mathit{S_k}$ classes and a calculation of habitat in % of substrate, the value of $\mathit{SI_S(S_i)}$ in equation (1) must be replaced by the formulation in equation (4). In this equation $\mathit{S_{i, | ||
| - | Let us now check a HSI calculation in any mesh of a hydraulic model. | + | (4) \[{SI_{i, |
| + | |||
| + | ==== Let us now check a HSI calculation in any mesh of a hydraulic model. | ||
| After building a .hab file with HABBY, choose a biological model for a stage, use the <hi # | After building a .hab file with HABBY, choose a biological model for a stage, use the <hi # | ||