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Contribution/Contribution.html

@@ -228,7 +228,7 @@ <h2 id="toc-title">On this page</h2>
 <h1>How can you upload your own tutorial or research page?</h1>
 <section id="how-to-install-quarto" class="level3">
 <h3 class="anchored" data-anchor-id="how-to-install-quarto">How to install Quarto</h3>
-<p>For installing and using Quarto correctly, please take a look at some helpul links:</p>
+<p>For installing and using Quarto correctly, please take a look at some helpful links:</p>
 <ul>
 <li>Installation: https://quarto.org/docs/get-started/</li>
 <li>Quarto basics: https://quarto.org/docs/get-started/hello/rstudio.html</li>
@@ -248,7 +248,7 @@ <h3 class="anchored" data-anchor-id="how-to-set-up-the-environment-and-compile-t
 <li>conda activate BlogQA</li>
 </ul>
 <ol start="3" type="1">
-<li>Install the dependecies as well as everthing needed regarding Jupyter and the BlogQA Kernel: In particular these are the following ones:</li>
+<li>Install the dependencies as well as everything needed regarding Jupyter and the BlogQA Kernel: In particular these are the following ones:</li>
 </ol>
 <ul>
 <li>conda create -n BlogQA python=3.9</li>
@@ -262,6 +262,7 @@ <h3 class="anchored" data-anchor-id="how-to-set-up-the-environment-and-compile-t
 <li>pip install qulacs</li>
 <li>pip install pyscf</li>
 </ul>
+<p>Also, these packages are necessary for the Documentation: * pip install sphinx * pip install sphinxcontrib * pip install sphinxcontrib-programoutput * pip install sphinx-rtd-theme</p>
 <ol start="4" type="1">
 <li>Preview with “quarto preview”</li>
 </ol>

FAQ.html

@@ -214,7 +214,7 @@ <h5 class="quarto-listing-category-title">Categories</h5><div class="quarto-list
 
 <div class="quarto-listing quarto-listing-container-default" id="listing-listing">
 <div class="list quarto-listing-default">
-<div class="quarto-post image-right" data-index="0" data-categories="code" data-listing-date-sort="1722556800000" data-listing-file-modified-sort="1731682437931" data-listing-date-modified-sort="NaN" data-listing-reading-time-sort="6">
+<div class="quarto-post image-right" data-index="0" data-categories="code" data-listing-date-sort="1722556800000" data-listing-file-modified-sort="1732019393644" data-listing-date-modified-sort="NaN" data-listing-reading-time-sort="6">
 <div class="thumbnail">
 <p><a href="./FAQ/FAQ.html"> <div class="listing-item-img-placeholder card-img-top" >&nbsp;</div> </a></p>
 </div>

Researches/Eigensolver/Eigensolver.html

@@ -392,11 +392,11 @@ <h3 class="anchored" data-anchor-id="projection-method">Projection Method</h3>
 <dl class="code-annotation-container-hidden code-annotation-container-grid">
 <dt data-target-cell="annotated-cell-5" data-target-annotation="1">1</dt>
 <dd>
-<span data-code-annotation="1" data-code-cell="annotated-cell-5" data-code-lines="11">The circuit list consists of the circuits preparing the i-th state. The addition is not an actual addition, but the concatenation operator for quantum circuits.</span>
+<span data-code-lines="11" data-code-annotation="1" data-code-cell="annotated-cell-5">The circuit list consists of the circuits preparing the i-th state. The addition is not an actual addition, but the concatenation operator for quantum circuits.</span>
 </dd>
 <dt data-target-cell="annotated-cell-5" data-target-annotation="2">2</dt>
 <dd>
-<span data-code-annotation="2" data-code-cell="annotated-cell-5" data-code-lines="14">This is the 0-projector.</span>
+<span data-code-lines="14" data-code-annotation="2" data-code-cell="annotated-cell-5">This is the 0-projector.</span>
 </dd>
 </dl>
 </div>
@@ -899,7 +899,7 @@ <h1>Chemistry example</h1>
 <dl class="code-annotation-container-hidden code-annotation-container-grid">
 <dt data-target-cell="annotated-cell-8" data-target-annotation="1">1</dt>
 <dd>
-<span data-code-annotation="1" data-code-cell="annotated-cell-8" data-code-lines="16">This is the given circuit, which consists of two rotations and two correlations. Thus, we are particularly able to analize the correlators and study their behaviour.</span>
+<span data-code-lines="16" data-code-annotation="1" data-code-cell="annotated-cell-8">This is the given circuit, which consists of two rotations and two correlations. Thus, we are particularly able to analize the correlators and study their behaviour.</span>
 </dd>
 </dl>
 </div>

Researches/quantum_classifier/quantum_classifier.html

@@ -326,31 +326,31 @@ <h2 class="anchored" data-anchor-id="variational-quantum-algorithms-and-quantum-
 <dl class="code-annotation-container-hidden code-annotation-container-grid">
 <dt data-target-cell="annotated-cell-2" data-target-annotation="1">1</dt>
 <dd>
-<span data-code-annotation="1" data-code-cell="annotated-cell-2" data-code-lines="1,2">Initialize tunable variables, that will be optimized later</span>
+<span data-code-cell="annotated-cell-2" data-code-annotation="1" data-code-lines="1,2">Initialize tunable variables, that will be optimized later</span>
 </dd>
 <dt data-target-cell="annotated-cell-2" data-target-annotation="2">2</dt>
 <dd>
-<span data-code-annotation="2" data-code-cell="annotated-cell-2" data-code-lines="3">Create a unitary/quantum circuit using a given problem structure</span>
+<span data-code-cell="annotated-cell-2" data-code-annotation="2" data-code-lines="3">Create a unitary/quantum circuit using a given problem structure</span>
 </dd>
 <dt data-target-cell="annotated-cell-2" data-target-annotation="3">3</dt>
 <dd>
-<span data-code-annotation="3" data-code-cell="annotated-cell-2" data-code-lines="5">Define an Observable whose expectation we want to measure</span>
+<span data-code-cell="annotated-cell-2" data-code-annotation="3" data-code-lines="5">Define an Observable whose expectation we want to measure</span>
 </dd>
 <dt data-target-cell="annotated-cell-2" data-target-annotation="4">4</dt>
 <dd>
-<span data-code-annotation="4" data-code-cell="annotated-cell-2" data-code-lines="6">Define the Objective/Loss function we want to minimize as the expectation value of the Observable after applying the Unitary</span>
+<span data-code-cell="annotated-cell-2" data-code-annotation="4" data-code-lines="6">Define the Objective/Loss function we want to minimize as the expectation value of the Observable after applying the Unitary</span>
 </dd>
 <dt data-target-cell="annotated-cell-2" data-target-annotation="5">5</dt>
 <dd>
-<span data-code-annotation="5" data-code-cell="annotated-cell-2" data-code-lines="8">Define some initial values for the variables we want to optimize</span>
+<span data-code-cell="annotated-cell-2" data-code-annotation="5" data-code-lines="8">Define some initial values for the variables we want to optimize</span>
 </dd>
 <dt data-target-cell="annotated-cell-2" data-target-annotation="6">6</dt>
 <dd>
-<span data-code-annotation="6" data-code-cell="annotated-cell-2" data-code-lines="9">Minimize the Objective through one of many different minimization methods to compute optimal variable assignments</span>
+<span data-code-cell="annotated-cell-2" data-code-annotation="6" data-code-lines="9">Minimize the Objective through one of many different minimization methods to compute optimal variable assignments</span>
 </dd>
 <dt data-target-cell="annotated-cell-2" data-target-annotation="7">7</dt>
 <dd>
-<span data-code-annotation="7" data-code-cell="annotated-cell-2" data-code-lines="10,11">Return the calculated parameters of the circuit and the minimal value of the Objective</span>
+<span data-code-cell="annotated-cell-2" data-code-annotation="7" data-code-lines="10,11">Return the calculated parameters of the circuit and the minimal value of the Objective</span>
 </dd>
 </dl>
 </div>
@@ -619,15 +619,15 @@ <h2 class="anchored" data-anchor-id="loss-function">3.4 Loss function</h2>
 <dl class="code-annotation-container-hidden code-annotation-container-grid">
 <dt data-target-cell="annotated-cell-10" data-target-annotation="1">1</dt>
 <dd>
-<span data-code-annotation="1" data-code-cell="annotated-cell-10" data-code-lines="12">We iterate through the training data and calculate the impact of that datapoint on the loss function</span>
+<span data-code-cell="annotated-cell-10" data-code-annotation="1" data-code-lines="12">We iterate through the training data and calculate the impact of that datapoint on the loss function</span>
 </dd>
 <dt data-target-cell="annotated-cell-10" data-target-annotation="2">2</dt>
 <dd>
-<span data-code-annotation="2" data-code-cell="annotated-cell-10" data-code-lines="15">The fidelity between the circuit result and the correct label state is expressed as a expectation value</span>
+<span data-code-cell="annotated-cell-10" data-code-annotation="2" data-code-lines="15">The fidelity between the circuit result and the correct label state is expressed as a expectation value</span>
 </dd>
 <dt data-target-cell="annotated-cell-10" data-target-annotation="3">3</dt>
 <dd>
-<span data-code-annotation="3" data-code-cell="annotated-cell-10" data-code-lines="16">A value in <span class="math inline">\([0,1]\)</span> gets added based on how good the current datapoint is treated by the circuit</span>
+<span data-code-cell="annotated-cell-10" data-code-annotation="3" data-code-lines="16">A value in <span class="math inline">\([0,1]\)</span> gets added based on how good the current datapoint is treated by the circuit</span>
 </dd>
 </dl>
 </div>