en:manuel_reference:methode_micro:verif_habby

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en:manuel_reference:methode_micro:verif_habby [2021/12/02 10:38] ylecoareren:manuel_reference:methode_micro:verif_habby [2021/12/02 10:48] ylecoarer
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 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.
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 (1_biv) \[HSI_i=SI_{H,V}(H_i,V_i)\] (1_biv) \[HSI_i=SI_{H,V}(H_i,V_i)\]
  
 +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) \[{SI_{i,S}(S_{i,1},S_{i,2},..S_{i,K})}=\frac{\sum_{k=1}^K S_{i,k}\times SI_S(S_k)}{100} \] 
  
-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 $\mathit{S_{i,k}}$ represents the % of substrate of class $\mathit{S_k}$ in mesh i, the substrate being described by a number K of particle size classes k ∈ $\mathit{[1,K]_N}$. 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 $\mathit{S_{i,k}}$ represents the % of substrate of class $\mathit{S_k}$ in mesh i, the substrate being described by a number K of particle size classes k ∈ $\mathit{[1,K]_N}$.
  
-Let us now check a HSI calculation in any mesh of a hydraulic model.+(4) \[{SI_{i,S}(S_{i,1},S_{i,2},..S_{i,K})}=\frac{\sum_{k=1}^K S_{i,k}\times SI_S(S_k)}{100} \] 
 + 
 +==== 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 #9BFFFF>**Create duplicate from selection**</hi> button to get 4 times that model. Then set the calculation options, to have not only the calculation for the 3 habitat variables, but also a calculation per variable. After building a .hab file with HABBY, choose a biological model for a stage, use the <hi #9BFFFF>**Create duplicate from selection**</hi> button to get 4 times that model. Then set the calculation options, to have not only the calculation for the 3 habitat variables, but also a calculation per variable.
  • en/manuel_reference/methode_micro/verif_habby.txt
  • Last modified: 2021/12/02 10:48
  • by ylecoarer