Semantics

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(Additive structure: diagonal)
m (notation for isomorphismes \cong instead of \sim)
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\begin{array}{rclcrcl}
 
\begin{array}{rclcrcl}
 
A\biorth &=& A\\
 
A\biorth &=& A\\
(A\tens B)\orth &\sim& A\orth\parr B\orth &\quad& \one\orth &\sim& \bot\\
+
(A\tens B)\orth &\cong& A\orth\parr B\orth &\quad& \one\orth &\cong& \bot\\
(A\parr B)\orth &\sim& A\orth\tens B\orth &\quad& \bot\orth &\sim& \one\\
+
(A\parr B)\orth &\cong& A\orth\tens B\orth &\quad& \bot\orth &\cong& \one\\
(A\with B)\orth &\sim& A\orth\plus B\orth &\quad& \top\orth &\sim& \zero\\
+
(A\with B)\orth &\cong& A\orth\plus B\orth &\quad& \top\orth &\cong& \zero\\
(A\plus B)\orth &\sim& A\orth\with B\orth &\quad& \zero\orth &\sim& \top\\
+
(A\plus B)\orth &\cong& A\orth\with B\orth &\quad& \zero\orth &\cong& \top\\
(\oc A)\orth &\sim& \wn A\orth\\
+
(\oc A)\orth &\cong& \wn A\orth\\
(\wn A)\orth &\sim& \oc A\orth\\[1ex]
+
(\wn A)\orth &\cong& \oc A\orth\\[1ex]
A\limp B &\sim& A\orth\parr B\\
+
A\limp B &\cong& A\orth\parr B\\
A\limp B &\sim& B\orth\limp A\orth\\
+
A\limp B &\cong& B\orth\limp A\orth\\
 
\end{array}
 
\end{array}
 
</math>
 
</math>
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<math>
 
<math>
 
\begin{array}{rcl}
 
\begin{array}{rcl}
A\tens\one &\sim& \one\tens A\sim A\\
+
A\tens\one &\cong& \one\tens A\cong A\\
A\parr\bot &\sim& \bot\parr A\sim A\\
+
A\parr\bot &\cong& \bot\parr A\cong A\\
A\with\top &\sim& \top\with A\sim A\\
+
A\with\top &\cong& \top\with A\cong A\\
A\plus\zero &\sim&\zero\plus A\sim A\\
+
A\plus\zero &\cong&\zero\plus A\cong A\\
 
\end{array}
 
\end{array}
 
</math>
 
</math>
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<math>
 
<math>
 
\begin{array}{rcl}
 
\begin{array}{rcl}
A\tens B &\sim& B\tens A\\
+
A\tens B &\cong& B\tens A\\
A\parr B &\sim& B\parr A\\
+
A\parr B &\cong& B\parr A\\
A\with B &\sim& B\with A\\
+
A\with B &\cong& B\with A\\
A\plus B &\sim& B\plus A\\
+
A\plus B &\cong& B\plus A\\
 
\end{array}
 
\end{array}
 
</math>
 
</math>
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<math>
 
<math>
 
\begin{array}{rcl}
 
\begin{array}{rcl}
(A\tens B)\tens C &\sim& A\tens(B\tens C)\\
+
(A\tens B)\tens C &\cong& A\tens(B\tens C)\\
(A\parr B)\parr C &\sim& A\parr(B\parr C)\\
+
(A\parr B)\parr C &\cong& A\parr(B\parr C)\\
(A\with B)\with C &\sim& A\with(B\with C)\\
+
(A\with B)\with C &\cong& A\with(B\with C)\\
(A\plus B)\plus C &\sim& A\plus(B\plus C)\\
+
(A\plus B)\plus C &\cong& A\plus(B\plus C)\\
 
\end{array}
 
\end{array}
 
</math>
 
</math>
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<math>
 
<math>
 
\begin{array}{rclcrcl}
 
\begin{array}{rclcrcl}
A\tens(B\plus C) &\sim& (A\tens B)\plus(A\tens C) &\quad&
+
A\tens(B\plus C) &\cong& (A\tens B)\plus(A\tens C) &\quad&
A\tens\zero &\sim& \zero\\
+
A\tens\zero &\cong& \zero\\
A\parr(B\with C) &\sim& (A\parr B)\with(A\parr C) &\quad&
+
A\parr(B\with C) &\cong& (A\parr B)\with(A\parr C) &\quad&
A\parr\top &\sim& \top\\
+
A\parr\top &\cong& \top\\
 
\end{array}
 
\end{array}
 
</math>
 
</math>
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<math>
 
<math>
 
\begin{array}{rclcrcl}
 
\begin{array}{rclcrcl}
\oc(A\with B) &\sim& \oc A\tens\oc B &\quad& \oc\top &\sim& \one\\
+
\oc(A\with B) &\cong& \oc A\tens\oc B &\quad& \oc\top &\cong& \one\\
\wn(A\plus B) &\sim& \wn A\parr\wn B &\quad& \wn\zero &\sim& \bot\\
+
\wn(A\plus B) &\cong& \wn A\parr\wn B &\quad& \wn\zero &\cong& \bot\\
 
\end{array}
 
\end{array}
 
</math>
 
</math>

Revision as of 09:45, 19 October 2009

Linear Logic has numerous semantics some of which are described in details in the next sections. We give here an overview of the common properties that one may find in most of these models. We will denote by A\longrightarrow B the fact that there is a canonical morphism from A to B and by A˜B the fact that there is a canonical isomorphism between A and B. By "canonical" we mean that these (iso)morphisms are natural transformations.

Contents

Linear negation


\begin{array}{rclcrcl}
  A\biorth &=& A\\
  (A\tens B)\orth &\cong& A\orth\parr B\orth &\quad& \one\orth  &\cong& \bot\\
  (A\parr B)\orth &\cong& A\orth\tens B\orth &\quad& \bot\orth  &\cong& \one\\
  (A\with B)\orth &\cong& A\orth\plus B\orth &\quad& \top\orth  &\cong& \zero\\
  (A\plus B)\orth &\cong& A\orth\with B\orth &\quad& \zero\orth &\cong& \top\\
  (\oc A)\orth &\cong& \wn A\orth\\
  (\wn A)\orth &\cong& \oc A\orth\\[1ex]
  A\limp B &\cong& A\orth\parr B\\
  A\limp B &\cong& B\orth\limp A\orth\\
\end{array}

Neutrals


\begin{array}{rcl}
  A\tens\one  &\cong& \one\tens A\cong A\\
  A\parr\bot  &\cong& \bot\parr A\cong A\\
  A\with\top  &\cong& \top\with A\cong A\\
  A\plus\zero &\cong&\zero\plus A\cong A\\
\end{array}

Commutativity


\begin{array}{rcl}
  A\tens B &\cong& B\tens A\\
  A\parr B &\cong& B\parr A\\
  A\with B &\cong& B\with A\\
  A\plus B &\cong& B\plus A\\
\end{array}

Associativity


\begin{array}{rcl}
  (A\tens B)\tens C &\cong& A\tens(B\tens C)\\
  (A\parr B)\parr C &\cong& A\parr(B\parr C)\\
  (A\with B)\with C &\cong& A\with(B\with C)\\
  (A\plus B)\plus C &\cong& A\plus(B\plus C)\\
\end{array}

Multiplicative semi-distributivity


\begin{array}{rcl}
  A\tens(B\parr C) &\longrightarrow& (A\tens B)\parr C\\
\end{array}

Multiplicative-additive distributivity


\begin{array}{rclcrcl}
  A\tens(B\plus C) &\cong& (A\tens B)\plus(A\tens C) &\quad&
  A\tens\zero &\cong& \zero\\
  A\parr(B\with C) &\cong& (A\parr B)\with(A\parr C) &\quad&
  A\parr\top &\cong& \top\\
\end{array}

Additive structure


\begin{array}{rcl}
  A\with B \longrightarrow A &\quad& A\with B \longrightarrow B\\
  (C\limp A)\with(C\limp B) &\longrightarrow& C\limp(A\with B)\\
  A &\longrightarrow& A\with A\\
  A \longrightarrow A\plus B &\quad& B \longrightarrow A\plus B\\
  (A\limp C)\with(B\limp C) &\longrightarrow& (A\plus B)\limp C\\
  A\plus A &\longrightarrow& A\\
\end{array}

Exponential structure


\begin{array}{rclcrcl}
  \oc A &\longrightarrow& A &\quad& A&\longrightarrow&\wn A\\
  \oc A &\longrightarrow& 1 &\quad& \bot &\longrightarrow& \wn A\\
  \oc A &\longrightarrow& \oc A\tens\oc A &\quad& 
  \wn A\parr\wn A &\longrightarrow& \wn A\\
  \oc A &\longrightarrow& \oc\oc A &\quad& \wn\wn A &\longrightarrow& \wn A\\
\end{array}

Monoidality of exponential


\begin{array}{rclcrcl}
  \oc A\tens\oc B &\longrightarrow& \oc(A\tens B) &\quad&
  \one &\longrightarrow& \oc\one\\
\end{array}

The exponential isomorphism


\begin{array}{rclcrcl}
  \oc(A\with B) &\cong& \oc A\tens\oc B &\quad& \oc\top &\cong& \one\\
  \wn(A\plus B) &\cong& \wn A\parr\wn B &\quad& \wn\zero &\cong& \bot\\
\end{array}

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