BFH - Boundary Flow and Head Package
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Abbreviation in Name file |
BFH when used with MODFLOW-LGR1 BFH2 when used with MODFLOW-LGR2 |
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Purpose |
The Boundary Flow and Head Package allows the child and parent models to be simulated independently using the boundary conditions obtained through the iterative process of LGR. |
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Documentation |
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Supported in |
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Other Notes |
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The Boundary Flow and Head (BFH) Package reads input data from the file indicated in the Name file as described by Harbaugh and others (2000, p. 7, 43) using the File Type BFH. Input for the BFH Package is created by LGR and requires that the coupling boundary conditions calculated by LGR be saved using variable IUCBHSV and (or) IUPBFSV of the LGR input file. For an independent child model simulation, IUCBHSV needs to be nonzero; for an independent parent model simulation, IUPBFSV needs to be nonzero.
The BFH Package and LGR cannot be used simultaneously. Thus, when using LGR, the Name file specified in the LGR control file cannot use file type BFH.
The procedure needed to run independent child or parent models with LGR boundary conditions is as follows:
1. | Use LGR to calculate and save the coupling boundary conditions. |
2. | Activate the BFH Package in the Name file with a file name that corresponds to the file saved on IUCBHSV or IUPBFSV for child and parent simulations, respectively. |
As discussed in the Running the Parent and Child Model Independently Using the Boundary Flow and Head (BFH) Package section, the BFH package can be used to evaluate the effects of model changes on the boundary conditions. In this case, the complementary boundary conditions also need to be saved when running LGR. For the child model, IUPBFSV needs be nonzero; for the parent model, IUCBHSV needs to be nonzero. If the file containing the complementary boundary conditions for the child or parent models is opened in the Name file on the unit number corresponding to IUPBFSV or IUCBHSV, respectively, then the BFH package will evaluate the discrepancies in the complementary boundary conditions.
Each of these files contains a header record and a list of the child and parent cells involved in the coupling, indicated by the layer, row, and column. For the child models, the corresponding adjoining parent cells and a node index is listed with each child cell. This is followed by a listing of the boundary head or flux values, corresponding to these cells, for each time step.
Example BFH Inputs
The options for the BFH Package can be controlled through inputs to LGR and the Name files. Using the three-dimensional example 3 in Appendix 1, a simulation using LGR is performed first. For an independent simulation of the child grid, the coupling boundary condition (specified head) is saved on unit 80 and the complementary boundary condition (boundary flux) is saved on unit 81.
The Name file for the child grid for the LGR simulation is:
LIST 26 ex3_child.out
BAS6 2 ex3_child.ba6
BCF6 21 ex3_child.bc6
DIS 29 ex3_child.dis
OC 20 ex3_child.oc
DATA(BINARY) 31 ex3_child.hed
DATA(BINARY) 41 ex3_child.flw
PCG 22 ex3_child_3.pcg
RIV 25 ex3_child.riv
DATA 80 ex3_child_bfh.hed
DATA 81 ex3_child_bfh.flw
DATA 51 ex3_child.bot
After successful completion of an LGR simulation, the child model can be simulated independently using the BFH Package. Only the Name file of the child grid needs to be modified. Activate BFH with a file name corresponding to the file where the coupling boundary conditions were saved. Although not required, in the example above, the complimentary boundary conditions were saved. If this file is opened in the Name file on the same unit number on which it was saved, the BFH Package will report any changes in the boundary fluxes of the child model. This is done in the example below. Use of # in the first column results in the line being ignored. This example is for MODFLOW-LGR1. For MODFLOW-LGR2, The file type BFH would be replaces with BFH2.
LIST 26 ex3_child.out
BAS6 2 ex3_child.ba6
BCF6 21 ex3_child.bc6
DIS 29 ex3_child.dis
OC 20 ex3_child.oc
DATA(BINARY) 31 ex3_child.hed
DATA(BINARY) 41 ex3_child.flw
PCG 22 ex3_child_3.pcg
RIV 25 ex3_child.riv
BFH 80 ex3_child_bfh.hed
#DATA 80 ex3_child_bfh.hed
DATA 81 ex3_child_bfh.flw
DATA 51 ex3_child.bot