<div class="func"><table class="func" width="100%"><tr><td class="tdleft"><code class="func">‣ NerveOfCatOneGroup</code>( <var class="Arg">G</var>, <var class="Arg">n</var> )</td><td class="tdright">( function )</td></tr></table></div>
<p>Inputs a cat-1-group <span class="SimpleMath">G</span> and a positive integer <span class="SimpleMath">n</span>. It returns the low-dimensional part of the nerve of <span class="SimpleMath">G</span> as a simplicial group of length <span class="SimpleMath">n</span>. <br /> <br /> This function applies both to cat-1-groups for which IsHapCatOneGroup(G) is true, and to cat-1-groups produced using the Xmod package. <br /> <br /> This function was implemented by <strong class="button">Van Luyen Le</strong>.</p>
<div class="func"><table class="func" width="100%"><tr><td class="tdleft"><code class="func">‣ EilenbergMacLaneSimplicialGroup</code>( <var class="Arg">G</var>, <var class="Arg">n</var>, <var class="Arg">dim</var> )</td><td class="tdright">( function )</td></tr></table></div>
<p>Inputs a group <span class="SimpleMath">G</span>, a positive integer <span class="SimpleMath">n</span>, and a positive integer <span class="SimpleMath">dim</span>. The function returns the first <span class="SimpleMath">1+dim</span> terms of a simplicial group with <span class="SimpleMath">n-1</span>st homotopy group equal to <span class="SimpleMath">G</span> and all other homotopy groups equal to zero. <br /> <br /> This function was implemented by <strong class="button">Van Luyen Le</strong>.</p>
<div class="func"><table class="func" width="100%"><tr><td class="tdleft"><code class="func">‣ EilenbergMacLaneSimplicialGroupMap</code></td><td class="tdright">( global variable )</td></tr></table></div>
<p>Inputs a group homomorphism <span class="SimpleMath">f:G→ Q</span>, a positive integer <span class="SimpleMath">n</span>, and a positive integer <span class="SimpleMath">dim</span>. The function returns the first <span class="SimpleMath">1+dim</span> terms of a simplicial group homomorphism <span class="SimpleMath">f:K(G,n) → K(Q,n)</span> of Eilenberg-MacLane simplicial groups. <br /> <br /> This function was implemented by <strong class="button">Van Luyen Le</strong>.</p>
<div class="func"><table class="func" width="100%"><tr><td class="tdleft"><code class="func">‣ MooreComplex</code>( <var class="Arg">G</var> )</td><td class="tdright">( function )</td></tr></table></div>
<p>Inputs a simplicial group <span class="SimpleMath">G</span> and returns its Moore complex as a <span class="SimpleMath">G</span>-complex. <br /> <br /> This function was implemented by <strong class="button">Van Luyen Le</strong>.</p>
<div class="func"><table class="func" width="100%"><tr><td class="tdleft"><code class="func">‣ ChainComplexOfSimplicialGroup</code>( <var class="Arg">G</var> )</td><td class="tdright">( function )</td></tr></table></div>
<p>Inputs a simplicial group <span class="SimpleMath">G</span> and returns the cellular chain complex <span class="SimpleMath">C</span> of a CW-space <span class="SimpleMath">X</span> represented by the homotopy type of the simplicial group. Thus the homology groups of <span class="SimpleMath">C</span> are the integral homology groups of <span class="SimpleMath">X</span>. <br /> <br /> This function was implemented by <strong class="button">Van Luyen Le</strong>.</p>
<div class="func"><table class="func" width="100%"><tr><td class="tdleft"><code class="func">‣ SimplicialGroupMap</code></td><td class="tdright">( global variable )</td></tr></table></div>
<p>Inputs a homomorphism <span class="SimpleMath">f:G→ Q</span> of simplicial groups. The function returns an induced map <span class="SimpleMath">f:C(G) → C(Q)</span> of chain complexes whose homology is the integral homology of the simplicial group G and Q respectively. <br /> <br /> This function was implemented by <strong class="button">Van Luyen Le</strong>.</p>
<div class="func"><table class="func" width="100%"><tr><td class="tdleft"><code class="func">‣ HomotopyGroup</code>( <var class="Arg">G</var>, <var class="Arg">n</var> )</td><td class="tdright">( function )</td></tr></table></div>
<p>Inputs a simplicial group <span class="SimpleMath">G</span> and a positive integer <span class="SimpleMath">n</span>. The integer <span class="SimpleMath">n</span> must be less than the length of <span class="SimpleMath">G</span>. It returns, as a group, the (n)-th homology group of its Moore complex. Thus HomotopyGroup(G,0) returns the "fundamental group" of <span class="SimpleMath">G</span>.</p>
<div class="func"><table class="func" width="100%"><tr><td class="tdleft"><code class="func">‣ BarResolutionBoundary</code></td><td class="tdright">( global variable )</td></tr></table></div>
<p>This function inputs a word <span class="SimpleMath">w</span> in the bar resolution module <spanclass="SimpleMath">B_n(G)</span> and returns its image under the boundary homomorphism <span class="SimpleMath">d_n: B_n(G) → B_n-1(G)</span> in the bar resolution. <br /> <br /> This function was implemented by <strong class="button">Van Luyen Le</strong>.</p>
<div class="func"><table class="func" width="100%"><tr><td class="tdleft"><code class="func">‣ BarResolutionHomotopy</code></td><td class="tdright">( global variable )</td></tr></table></div>
<p>This function inputs a word <span class="SimpleMath">w</span> in the bar resolution module <spanclass="SimpleMath">B_n(G)</span> and returns its image under the contracting homotopy <span class="SimpleMath">h_n: B_n(G) → B_n+1(G)</span> in the bar resolution. <br /> <br /> This function is currently being implemented by <strong class="button">Van Luyen Le</strong>.</p>
<h5>25.1-11 Representation of elements in the bar complex</h5>
<div class="func"><table class="func" width="100%"><tr><td class="tdleft"><code class="func">‣ Representation of elements in the bar complex</code></td><td class="tdright">( global variable )</td></tr></table></div>
<p>For a group G we denote by <span class="SimpleMath">BC_n(G)</span> the free abelian group with basis the lists <span class="SimpleMath">[g_1 | g_2 | ... | g_n]</span> where the <span class="SimpleMath">g_i</span> range over <span class="SimpleMath">G</span>. <br /> <br /> We represent a word <br /> <br /> <span class="SimpleMath">w = [g_11 | g_12 | ... | g_1n] - [g_21 | g_22 | ... | g_2n] + ... + [g_k1 | g_k2 | ... | g_kn]</span> <br /> <br /> in <span class="SimpleMath">BC_n(G)</span> as a list of lists: <br /> <br /> <span class="SimpleMath">[ [+1,g_11 , g_12 , ... , g_1n] , [-1, g_21 , g_22 , ... | g_2n] + ... + [+1, g_k1 , g_k2 , ... , g_kn]</span>.</p>
<div class="func"><table class="func" width="100%"><tr><td class="tdleft"><code class="func">‣ BarComplexBoundary</code></td><td class="tdright">( global variable )</td></tr></table></div>
<p>This function inputs a word <span class="SimpleMath">w</span> in the n-th term of the bar complex <span class="SimpleMath">BC_n(G)</span> and returns its image under the boundary homomorphism <span class="SimpleMath">d_n: BC_n(G) → BC_n-1(G)</span> in the bar complex. <br /> <br /> This function was implemented by <strong class="button">Van Luyen Le</strong>.</p>
<div class="func"><table class="func" width="100%"><tr><td class="tdleft"><code class="func">‣ BarResolutionEquivalence</code>( <var class="Arg">R</var> )</td><td class="tdright">( function )</td></tr></table></div>
<p>This function inputs a free <span class="SimpleMath">ZG</span>-resolution <span class="SimpleMath">R</span>. It returns a component object HE with components</p>
<ul>
<li><p>HE!.phi(n,w) is a function which inputs a non-negative integer <span class="SimpleMath">n</span> and a word <span class="SimpleMath">w</span> in <span class="SimpleMath">B_n(G)</span>. It returns the image of <span class="SimpleMath">w</span> in <span class="SimpleMath">R_n</span> under a chain equivalence <span class="SimpleMath">ϕ: B_n(G) → R_n</span>.</p>
</li>
<li><p>HE!.psi(n,w) is a function which inputs a non-negative integer <span class="SimpleMath">n</span> and a word <span class="SimpleMath">w</span> in <span class="SimpleMath">R_n</span>. It returns the image of <span class="SimpleMath">w</span> in <span class="SimpleMath">B_n(G)</span> under a chain equivalence <span class="SimpleMath">ψ: R_n → B_n(G)</span>.</p>
</li>
<li><p>HE!.equiv(n,w) is a function which inputs a non-negative integer <span class="SimpleMath">n</span> and a word <span class="SimpleMath">w</span> in <span class="SimpleMath">B_n(G)</span>. It returns the image of <span class="SimpleMath">w</span> in <span class="SimpleMath">B_n+1(G)</span> under a <span class="SimpleMath">ZG</span>-equivariant homomorphism <br /> <br /> <span class="SimpleMath">equiv(n,-) : B_n(G) → B_n+1(G)</span> <br /> <br /> satisfying</p>
<div class="func"><table class="func" width="100%"><tr><td class="tdleft"><code class="func">‣ BarComplexEquivalence</code>( <var class="Arg">R</var> )</td><td class="tdright">( function )</td></tr></table></div>
<p>This function inputs a free <span class="SimpleMath">ZG</span>-resolution <span class="SimpleMath">R</span>. It first constructs the chain complex <span class="SimpleMath">T=TensorWithIntegerts(R)</span>. The function returns a component object HE with components</p>
<ul>
<li><p>HE!.phi(n,w) is a function which inputs a non-negative integer <span class="SimpleMath">n</span> and a word <span class="SimpleMath">w</span> in <span class="SimpleMath">BC_n(G)</span>. It returns the image of <span class="SimpleMath">w</span> in <span class="SimpleMath">T_n</span> under a chain equivalence <span class="SimpleMath">ϕ: BC_n(G) → T_n</span>.</p>
</li>
<li><p>HE!.psi(n,w) is a function which inputs a non-negative integer <span class="SimpleMath">n</span> and an element <span class="SimpleMath">w</span> in <span class="SimpleMath">T_n</span>. It returns the image of <span class="SimpleMath">w</span> in <span class="SimpleMath">BC_n(G)</span> under a chain equivalence <span class="SimpleMath">ψ: T_n → BC_n(G)</span>.</p>
</li>
<li><p>HE!.equiv(n,w) is a function which inputs a non-negative integer <span class="SimpleMath">n</span> and a word <span class="SimpleMath">w</span> in <span class="SimpleMath">BC_n(G)</span>. It returns the image of <span class="SimpleMath">w</span> in <span class="SimpleMath">BC_n+1(G)</span> under a homomorphism <br /> <br /> <span class="SimpleMath">equiv(n,-) : BC_n(G) → BC_n+1(G)</span> <br /> <br /> satisfying</p>
<h5>25.1-15 Representation of elements in the bar cocomplex</h5>
<div class="func"><table class="func" width="100%"><tr><td class="tdleft"><code class="func">‣ Representation of elements in the bar cocomplex</code></td><td class="tdright">( global variable )</td></tr></table></div>
<p>For a group G we denote by <span class="SimpleMath">BC^n(G)</span> the free abelian group with basis the lists <span class="SimpleMath">[g_1 | g_2 | ... | g_n]</span> where the <span class="SimpleMath">g_i</span> range over <span class="SimpleMath">G</span>. <br /> <br /> We represent a word <br /> <br /> <span class="SimpleMath">w = [g_11 | g_12 | ... | g_1n] - [g_21 | g_22 | ... | g_2n] + ... + [g_k1 | g_k2 | ... | g_kn]</span> <br /> <br /> in <span class="SimpleMath">BC^n(G)</span> as a list of lists: <br /> <br /> <span class="SimpleMath">[ [+1,g_11 , g_12 , ... , g_1n] , [-1, g_21 , g_22 , ... | g_2n] + ... + [+1, g_k1 , g_k2 , ... , g_kn]</span>.</p>
<div class="func"><table class="func" width="100%"><tr><td class="tdleft"><code class="func">‣ BarCocomplexCoboundary</code></td><td class="tdright">( global variable )</td></tr></table></div>
<p>This function inputs a word <span class="SimpleMath">w</span> in the n-th term of the bar cocomplex <span class="SimpleMath">BC^n(G)</span> and returns its image under the coboundary homomorphism <span class="SimpleMath">d^n: BC^n(G) → BC^n+1(G)</span> in the bar cocomplex. <br /> <br /> This function was implemented by <strong class="button">Van Luyen Le</strong>.</p>
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