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362 changes: 181 additions & 181 deletions build/index.html

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52 changes: 26 additions & 26 deletions core/allocation.html
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Expand Up @@ -623,7 +623,7 @@ <h1 data-number="5"><span class="header-section-number">5</span> Solving the all
<section id="example" class="level2" data-number="5.1">
<h2 data-number="5.1" class="anchored" data-anchor-id="example"><span class="header-section-number">5.1</span> Example</h2>
<p>The following is an example of an optimization problem for the example shown <a href="../python/examples.html#model-with-allocation">here</a>:</p>
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<div class="sourceCode cell-code" id="cb1"><pre class="sourceCode julia code-with-copy"><code class="sourceCode julia"><span id="cb1-1"><a href="#cb1-1" aria-hidden="true" tabindex="-1"></a><span class="im">using</span> <span class="bu">Ribasim</span></span>
Expand All @@ -648,45 +648,45 @@ <h2 data-number="5.1" class="anchored" data-anchor-id="example"><span class="hea
<span id="cb1-20"><a href="#cb1-20" aria-hidden="true" tabindex="-1"></a><span class="fu">println</span>(p.allocation.allocation_models[<span class="fl">1</span>].problem)</span></code><button title="Copy to Clipboard" class="code-copy-button"><i class="bi"></i></button></pre></div>
</details>
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<pre><code>Min F_abs_user_demand[UserDemand #13] + F_abs_user_demand[UserDemand #6] + F_abs_user_demand[UserDemand #3] + F_abs_basin[Basin #12] + F_abs_basin[Basin #5] + F_abs_basin[Basin #2]
<pre><code>Min F_abs_user_demand[UserDemand #3] + F_abs_user_demand[UserDemand #6] + F_abs_user_demand[UserDemand #13] + F_abs_basin[Basin #2] + F_abs_basin[Basin #5] + F_abs_basin[Basin #12]
Subject to
F[(TabulatedRatingCurve #7, Basin #12)] ≥ 0
F[(Basin #12, UserDemand #13)] ≥ 0
F[(TabulatedRatingCurve #7, Terminal #10)] ≥ 0
F[(UserDemand #13, Terminal #10)] ≥ 0
F[(Basin #5, Basin #2)] ≥ 0
F[(Basin #5, TabulatedRatingCurve #7)] ≥ 0
F[(FlowBoundary #1, Basin #2)] ≥ 0
F[(UserDemand #13, Terminal #10)] ≥ 0
F[(Basin #2, Basin #5)] ≥ 0
F[(Basin #12, UserDemand #13)] ≥ 0
F[(TabulatedRatingCurve #7, Basin #12)] ≥ 0
F[(Basin #5, UserDemand #6)] ≥ 0
F[(Basin #5, TabulatedRatingCurve #7)] ≥ 0
F[(Basin #2, UserDemand #3)] ≥ 0
F_basin_in[Basin #12] ≥ 0
F_basin_in[Basin #5] ≥ 0
F[(TabulatedRatingCurve #7, Terminal #10)] ≥ 0
F[(Basin #5, Basin #2)] ≥ 0
F_basin_in[Basin #2] ≥ 0
F_basin_out[Basin #12] ≥ 0
F_basin_out[Basin #5] ≥ 0
F_basin_in[Basin #5] ≥ 0
F_basin_in[Basin #12] ≥ 0
F_basin_out[Basin #2] ≥ 0
abs_positive_user_demand[UserDemand #13] : -F[(Basin #12, UserDemand #13)] + F_abs_user_demand[UserDemand #13] ≥ 0
abs_positive_user_demand[UserDemand #6] : -F[(Basin #5, UserDemand #6)] + F_abs_user_demand[UserDemand #6] ≥ -1.5
F_basin_out[Basin #5] ≥ 0
F_basin_out[Basin #12] ≥ 0
abs_positive_user_demand[UserDemand #3] : -F[(Basin #2, UserDemand #3)] + F_abs_user_demand[UserDemand #3] ≥ 0
abs_negative_user_demand[UserDemand #13] : F[(Basin #12, UserDemand #13)] + F_abs_user_demand[UserDemand #13] ≥ 0
abs_negative_user_demand[UserDemand #6] : F[(Basin #5, UserDemand #6)] + F_abs_user_demand[UserDemand #6] ≥ 1.5
abs_positive_user_demand[UserDemand #6] : -F[(Basin #5, UserDemand #6)] + F_abs_user_demand[UserDemand #6] ≥ -1.5
abs_positive_user_demand[UserDemand #13] : -F[(Basin #12, UserDemand #13)] + F_abs_user_demand[UserDemand #13] ≥ 0
abs_negative_user_demand[UserDemand #3] : F[(Basin #2, UserDemand #3)] + F_abs_user_demand[UserDemand #3] ≥ 0
abs_positive_basin[Basin #12] : -F_basin_in[Basin #12] + F_abs_basin[Basin #12] ≥ 0
abs_positive_basin[Basin #5] : -F_basin_in[Basin #5] + F_abs_basin[Basin #5] ≥ 0
abs_negative_user_demand[UserDemand #6] : F[(Basin #5, UserDemand #6)] + F_abs_user_demand[UserDemand #6] ≥ 1.5
abs_negative_user_demand[UserDemand #13] : F[(Basin #12, UserDemand #13)] + F_abs_user_demand[UserDemand #13] ≥ 0
abs_positive_basin[Basin #2] : -F_basin_in[Basin #2] + F_abs_basin[Basin #2] ≥ 0
abs_negative_basin[Basin #12] : F_basin_in[Basin #12] + F_abs_basin[Basin #12] ≥ 0
abs_negative_basin[Basin #5] : F_basin_in[Basin #5] + F_abs_basin[Basin #5] ≥ 0
abs_positive_basin[Basin #5] : -F_basin_in[Basin #5] + F_abs_basin[Basin #5] ≥ 0
abs_positive_basin[Basin #12] : -F_basin_in[Basin #12] + F_abs_basin[Basin #12] ≥ 0
abs_negative_basin[Basin #2] : F_basin_in[Basin #2] + F_abs_basin[Basin #2] ≥ 0
flow_conservation[Basin #12] : -F[(TabulatedRatingCurve #7, Basin #12)] + F[(Basin #12, UserDemand #13)] + F_basin_in[Basin #12] - F_basin_out[Basin #12] = 0
flow_conservation[Basin #5] : F[(Basin #5, Basin #2)] - F[(Basin #2, Basin #5)] + F[(Basin #5, UserDemand #6)] + F[(Basin #5, TabulatedRatingCurve #7)] + F_basin_in[Basin #5] - F_basin_out[Basin #5] = 0
flow_conservation[Basin #2] : -F[(Basin #5, Basin #2)] - F[(FlowBoundary #1, Basin #2)] + F[(Basin #2, Basin #5)] + F[(Basin #2, UserDemand #3)] + F_basin_in[Basin #2] - F_basin_out[Basin #2] = 0
abs_negative_basin[Basin #5] : F_basin_in[Basin #5] + F_abs_basin[Basin #5] ≥ 0
abs_negative_basin[Basin #12] : F_basin_in[Basin #12] + F_abs_basin[Basin #12] ≥ 0
flow_conservation[Basin #2] : -F[(FlowBoundary #1, Basin #2)] + F[(Basin #2, Basin #5)] + F[(Basin #2, UserDemand #3)] - F[(Basin #5, Basin #2)] + F_basin_in[Basin #2] - F_basin_out[Basin #2] = 0
flow_conservation[Basin #5] : F[(Basin #5, TabulatedRatingCurve #7)] - F[(Basin #2, Basin #5)] + F[(Basin #5, UserDemand #6)] + F[(Basin #5, Basin #2)] + F_basin_in[Basin #5] - F_basin_out[Basin #5] = 0
flow_conservation[Basin #12] : F[(Basin #12, UserDemand #13)] - F[(TabulatedRatingCurve #7, Basin #12)] + F_basin_in[Basin #12] - F_basin_out[Basin #12] = 0
source[(FlowBoundary #1, Basin #2)] : F[(FlowBoundary #1, Basin #2)] ≤ 1
return_flow[UserDemand #13] : F[(UserDemand #13, Terminal #10)] ≤ 0
fractional_flow[(TabulatedRatingCurve #7, Basin #12)] : F[(TabulatedRatingCurve #7, Basin #12)] - 0.4 F[(Basin #5, TabulatedRatingCurve #7)] ≤ 0
basin_outflow[Basin #12] : F_basin_out[Basin #12] ≤ 0
basin_outflow[Basin #5] : F_basin_out[Basin #5] ≤ 0
fractional_flow[(TabulatedRatingCurve #7, Basin #12)] : -0.4 F[(Basin #5, TabulatedRatingCurve #7)] + F[(TabulatedRatingCurve #7, Basin #12)] ≤ 0
basin_outflow[Basin #2] : F_basin_out[Basin #2] ≤ 0
basin_outflow[Basin #5] : F_basin_out[Basin #5] ≤ 0
basin_outflow[Basin #12] : F_basin_out[Basin #12] ≤ 0
</code></pre>
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2 changes: 1 addition & 1 deletion core/equations.html
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Expand Up @@ -427,7 +427,7 @@ <h2 data-number="2.1" class="anchored" data-anchor-id="sec-reduction_factor"><sp
\end{cases}
\end{align}\]</span></p>
<p>Here <span class="math inline">\(p &gt; 0\)</span> is the threshold value which determines the interval <span class="math inline">\([0,p]\)</span> of the smooth transition between <span class="math inline">\(0\)</span> and <span class="math inline">\(1\)</span>, see the plot below.</p>
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<div class="sourceCode cell-code" id="cb1"><pre class="sourceCode python code-with-copy"><code class="sourceCode python"><span id="cb1-1"><a href="#cb1-1" aria-hidden="true" tabindex="-1"></a><span class="im">import</span> numpy <span class="im">as</span> np</span>
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4 changes: 2 additions & 2 deletions core/validation.html
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Expand Up @@ -262,7 +262,7 @@ <h1 class="title">Validation</h1>
<section id="connectivity" class="level1" data-number="1">
<h1 data-number="1"><span class="header-section-number">1</span> Connectivity</h1>
<p>In the table below, each column shows which node types are allowed to be downstream (or ‘down-control’) of the node type at the top of the column.</p>
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<div class="sourceCode cell-code" id="cb1"><pre class="sourceCode julia code-with-copy"><code class="sourceCode julia"><span id="cb1-1"><a href="#cb1-1" aria-hidden="true" tabindex="-1"></a><span class="im">using</span> <span class="bu">Ribasim</span></span>
Expand Down Expand Up @@ -546,7 +546,7 @@ <h1 data-number="1"><span class="header-section-number">1</span> Connectivity</h
<section id="neighbor-amounts" class="level1" data-number="2">
<h1 data-number="2"><span class="header-section-number">2</span> Neighbor amounts</h1>
<p>The table below shows for each node type between which bounds the amount of in- and outneighbors must be, for both flow and control edges.</p>
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<div class="sourceCode cell-code" id="cb2"><pre class="sourceCode julia code-with-copy"><code class="sourceCode julia"><span id="cb2-1"><a href="#cb2-1" aria-hidden="true" tabindex="-1"></a>flow_in_min <span class="op">=</span> <span class="fu">Vector</span><span class="dt">{String}</span>()</span>
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2 changes: 1 addition & 1 deletion python/test-models.html
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Expand Up @@ -227,7 +227,7 @@ <h1 class="title">Test models</h1>


<p>Ribasim developers use the following models in their testbench and in order to test new features.</p>
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<div class="sourceCode cell-code" id="cb1"><pre class="sourceCode python code-with-copy"><code class="sourceCode python"><span id="cb1-1"><a href="#cb1-1" aria-hidden="true" tabindex="-1"></a><span class="im">import</span> ribasim_testmodels</span>
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2 changes: 1 addition & 1 deletion search.json
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Expand Up @@ -850,7 +850,7 @@
"href": "core/allocation.html#example",
"title": "Allocation",
"section": "5.1 Example",
"text": "5.1 Example\nThe following is an example of an optimization problem for the example shown here:\n\n\nCode\nusing Ribasim\nusing Ribasim: NodeID\nusing SQLite\nusing ComponentArrays: ComponentVector\n\ntoml_path = normpath(@__DIR__, \"../../generated_testmodels/allocation_example/ribasim.toml\")\np = Ribasim.Model(toml_path).integrator.p\nu = ComponentVector(; storage = zeros(length(p.basin.node_id)))\n\nallocation_model = p.allocation.allocation_models[1]\nt = 0.0\npriority_idx = 1\n\nRibasim.set_flow!(p.graph, NodeID(:FlowBoundary, 1), NodeID(:Basin, 2), 1.0)\n\nRibasim.adjust_source_capacities!(allocation_model, p, priority_idx)\nRibasim.adjust_edge_capacities!(allocation_model, p, priority_idx)\nRibasim.set_objective_priority!(allocation_model, p, u, t, priority_idx)\n\nprintln(p.allocation.allocation_models[1].problem)\n\n\nMin F_abs_user_demand[UserDemand #13] + F_abs_user_demand[UserDemand #6] + F_abs_user_demand[UserDemand #3] + F_abs_basin[Basin #12] + F_abs_basin[Basin #5] + F_abs_basin[Basin #2]\nSubject to\n F[(TabulatedRatingCurve #7, Basin #12)] ≥ 0\n F[(Basin #12, UserDemand #13)] ≥ 0\n F[(TabulatedRatingCurve #7, Terminal #10)] ≥ 0\n F[(UserDemand #13, Terminal #10)] ≥ 0\n F[(Basin #5, Basin #2)] ≥ 0\n F[(FlowBoundary #1, Basin #2)] ≥ 0\n F[(Basin #2, Basin #5)] ≥ 0\n F[(Basin #5, UserDemand #6)] ≥ 0\n F[(Basin #5, TabulatedRatingCurve #7)] ≥ 0\n F[(Basin #2, UserDemand #3)] ≥ 0\n F_basin_in[Basin #12] ≥ 0\n F_basin_in[Basin #5] ≥ 0\n F_basin_in[Basin #2] ≥ 0\n F_basin_out[Basin #12] ≥ 0\n F_basin_out[Basin #5] ≥ 0\n F_basin_out[Basin #2] ≥ 0\n abs_positive_user_demand[UserDemand #13] : -F[(Basin #12, UserDemand #13)] + F_abs_user_demand[UserDemand #13] ≥ 0\n abs_positive_user_demand[UserDemand #6] : -F[(Basin #5, UserDemand #6)] + F_abs_user_demand[UserDemand #6] ≥ -1.5\n abs_positive_user_demand[UserDemand #3] : -F[(Basin #2, UserDemand #3)] + F_abs_user_demand[UserDemand #3] ≥ 0\n abs_negative_user_demand[UserDemand #13] : F[(Basin #12, UserDemand #13)] + F_abs_user_demand[UserDemand #13] ≥ 0\n abs_negative_user_demand[UserDemand #6] : F[(Basin #5, UserDemand #6)] + F_abs_user_demand[UserDemand #6] ≥ 1.5\n abs_negative_user_demand[UserDemand #3] : F[(Basin #2, UserDemand #3)] + F_abs_user_demand[UserDemand #3] ≥ 0\n abs_positive_basin[Basin #12] : -F_basin_in[Basin #12] + F_abs_basin[Basin #12] ≥ 0\n abs_positive_basin[Basin #5] : -F_basin_in[Basin #5] + F_abs_basin[Basin #5] ≥ 0\n abs_positive_basin[Basin #2] : -F_basin_in[Basin #2] + F_abs_basin[Basin #2] ≥ 0\n abs_negative_basin[Basin #12] : F_basin_in[Basin #12] + F_abs_basin[Basin #12] ≥ 0\n abs_negative_basin[Basin #5] : F_basin_in[Basin #5] + F_abs_basin[Basin #5] ≥ 0\n abs_negative_basin[Basin #2] : F_basin_in[Basin #2] + F_abs_basin[Basin #2] ≥ 0\n flow_conservation[Basin #12] : -F[(TabulatedRatingCurve #7, Basin #12)] + F[(Basin #12, UserDemand #13)] + F_basin_in[Basin #12] - F_basin_out[Basin #12] = 0\n flow_conservation[Basin #5] : F[(Basin #5, Basin #2)] - F[(Basin #2, Basin #5)] + F[(Basin #5, UserDemand #6)] + F[(Basin #5, TabulatedRatingCurve #7)] + F_basin_in[Basin #5] - F_basin_out[Basin #5] = 0\n flow_conservation[Basin #2] : -F[(Basin #5, Basin #2)] - F[(FlowBoundary #1, Basin #2)] + F[(Basin #2, Basin #5)] + F[(Basin #2, UserDemand #3)] + F_basin_in[Basin #2] - F_basin_out[Basin #2] = 0\n source[(FlowBoundary #1, Basin #2)] : F[(FlowBoundary #1, Basin #2)] ≤ 1\n return_flow[UserDemand #13] : F[(UserDemand #13, Terminal #10)] ≤ 0\n fractional_flow[(TabulatedRatingCurve #7, Basin #12)] : F[(TabulatedRatingCurve #7, Basin #12)] - 0.4 F[(Basin #5, TabulatedRatingCurve #7)] ≤ 0\n basin_outflow[Basin #12] : F_basin_out[Basin #12] ≤ 0\n basin_outflow[Basin #5] : F_basin_out[Basin #5] ≤ 0\n basin_outflow[Basin #2] : F_basin_out[Basin #2] ≤ 0",
"text": "5.1 Example\nThe following is an example of an optimization problem for the example shown here:\n\n\nCode\nusing Ribasim\nusing Ribasim: NodeID\nusing SQLite\nusing ComponentArrays: ComponentVector\n\ntoml_path = normpath(@__DIR__, \"../../generated_testmodels/allocation_example/ribasim.toml\")\np = Ribasim.Model(toml_path).integrator.p\nu = ComponentVector(; storage = zeros(length(p.basin.node_id)))\n\nallocation_model = p.allocation.allocation_models[1]\nt = 0.0\npriority_idx = 1\n\nRibasim.set_flow!(p.graph, NodeID(:FlowBoundary, 1), NodeID(:Basin, 2), 1.0)\n\nRibasim.adjust_source_capacities!(allocation_model, p, priority_idx)\nRibasim.adjust_edge_capacities!(allocation_model, p, priority_idx)\nRibasim.set_objective_priority!(allocation_model, p, u, t, priority_idx)\n\nprintln(p.allocation.allocation_models[1].problem)\n\n\nMin F_abs_user_demand[UserDemand #3] + F_abs_user_demand[UserDemand #6] + F_abs_user_demand[UserDemand #13] + F_abs_basin[Basin #2] + F_abs_basin[Basin #5] + F_abs_basin[Basin #12]\nSubject to\n F[(Basin #5, TabulatedRatingCurve #7)] ≥ 0\n F[(FlowBoundary #1, Basin #2)] ≥ 0\n F[(UserDemand #13, Terminal #10)] ≥ 0\n F[(Basin #2, Basin #5)] ≥ 0\n F[(Basin #12, UserDemand #13)] ≥ 0\n F[(TabulatedRatingCurve #7, Basin #12)] ≥ 0\n F[(Basin #5, UserDemand #6)] ≥ 0\n F[(Basin #2, UserDemand #3)] ≥ 0\n F[(TabulatedRatingCurve #7, Terminal #10)] ≥ 0\n F[(Basin #5, Basin #2)] ≥ 0\n F_basin_in[Basin #2] ≥ 0\n F_basin_in[Basin #5] ≥ 0\n F_basin_in[Basin #12] ≥ 0\n F_basin_out[Basin #2] ≥ 0\n F_basin_out[Basin #5] ≥ 0\n F_basin_out[Basin #12] ≥ 0\n abs_positive_user_demand[UserDemand #3] : -F[(Basin #2, UserDemand #3)] + F_abs_user_demand[UserDemand #3] ≥ 0\n abs_positive_user_demand[UserDemand #6] : -F[(Basin #5, UserDemand #6)] + F_abs_user_demand[UserDemand #6] ≥ -1.5\n abs_positive_user_demand[UserDemand #13] : -F[(Basin #12, UserDemand #13)] + F_abs_user_demand[UserDemand #13] ≥ 0\n abs_negative_user_demand[UserDemand #3] : F[(Basin #2, UserDemand #3)] + F_abs_user_demand[UserDemand #3] ≥ 0\n abs_negative_user_demand[UserDemand #6] : F[(Basin #5, UserDemand #6)] + F_abs_user_demand[UserDemand #6] ≥ 1.5\n abs_negative_user_demand[UserDemand #13] : F[(Basin #12, UserDemand #13)] + F_abs_user_demand[UserDemand #13] ≥ 0\n abs_positive_basin[Basin #2] : -F_basin_in[Basin #2] + F_abs_basin[Basin #2] ≥ 0\n abs_positive_basin[Basin #5] : -F_basin_in[Basin #5] + F_abs_basin[Basin #5] ≥ 0\n abs_positive_basin[Basin #12] : -F_basin_in[Basin #12] + F_abs_basin[Basin #12] ≥ 0\n abs_negative_basin[Basin #2] : F_basin_in[Basin #2] + F_abs_basin[Basin #2] ≥ 0\n abs_negative_basin[Basin #5] : F_basin_in[Basin #5] + F_abs_basin[Basin #5] ≥ 0\n abs_negative_basin[Basin #12] : F_basin_in[Basin #12] + F_abs_basin[Basin #12] ≥ 0\n flow_conservation[Basin #2] : -F[(FlowBoundary #1, Basin #2)] + F[(Basin #2, Basin #5)] + F[(Basin #2, UserDemand #3)] - F[(Basin #5, Basin #2)] + F_basin_in[Basin #2] - F_basin_out[Basin #2] = 0\n flow_conservation[Basin #5] : F[(Basin #5, TabulatedRatingCurve #7)] - F[(Basin #2, Basin #5)] + F[(Basin #5, UserDemand #6)] + F[(Basin #5, Basin #2)] + F_basin_in[Basin #5] - F_basin_out[Basin #5] = 0\n flow_conservation[Basin #12] : F[(Basin #12, UserDemand #13)] - F[(TabulatedRatingCurve #7, Basin #12)] + F_basin_in[Basin #12] - F_basin_out[Basin #12] = 0\n source[(FlowBoundary #1, Basin #2)] : F[(FlowBoundary #1, Basin #2)] ≤ 1\n return_flow[UserDemand #13] : F[(UserDemand #13, Terminal #10)] ≤ 0\n fractional_flow[(TabulatedRatingCurve #7, Basin #12)] : -0.4 F[(Basin #5, TabulatedRatingCurve #7)] + F[(TabulatedRatingCurve #7, Basin #12)] ≤ 0\n basin_outflow[Basin #2] : F_basin_out[Basin #2] ≤ 0\n basin_outflow[Basin #5] : F_basin_out[Basin #5] ≤ 0\n basin_outflow[Basin #12] : F_basin_out[Basin #12] ≤ 0",
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