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(*
Title: Allen's qualitative temporal calculus
Author: Fadoua Ghourabi (fadouaghourabi@gmail.com)
Affiliation: Ochanomizu University, Japan
*)
theory axioms
imports
Main xor_cal
begin
section \<open>Axioms\<close>
text\<open>We formalize Allen's definition of theory of time in term of intervals (Allen, 1983).
Two relations, namely meets and equality, are defined between intervals. Two interval meets if they are adjacent
A set of 5 axioms ((M1) $\sim$ (M5)) are then defined based on relation meets.\<close>
text\<open>We define a class interval whose assumptions are (i) properties of relations meets and, (ii) axioms (M1) $\sim$ (M5).\<close>
class interval =
fixes
meets::"'a \<Rightarrow> 'a \<Rightarrow> bool" (infixl "\<parallel>" 60) and
\<I>::"'a \<Rightarrow> bool"
assumes
meets_atrans:"\<lbrakk>(p\<parallel>q);(q\<parallel>r)\<rbrakk> \<Longrightarrow> \<not>(p\<parallel>r)" and
meets_irrefl:"\<I> p \<Longrightarrow> \<not>(p\<parallel>p)" and
meets_asym:"(p\<parallel>q) \<Longrightarrow> \<not>(q\<parallel>p)" and
meets_wd:"p\<parallel>q \<Longrightarrow> \<I> p \<and> \<I> q" and
(**** Time axioms ******)
M1:"\<lbrakk>(p\<parallel>q); (p\<parallel>s); (r\<parallel>q)\<rbrakk> \<Longrightarrow> (r\<parallel>s)" and
M2:"\<lbrakk>(p\<parallel>q) ; (r\<parallel>s)\<rbrakk> \<Longrightarrow> p\<parallel>s \<oplus> ((\<exists>t. (p\<parallel>t)\<and>(t\<parallel>s)) \<oplus> (\<exists>t. (r\<parallel>t)\<and>(t\<parallel>q)))" and
M3:"\<I> p \<Longrightarrow> (\<exists>q r. q\<parallel>p \<and> p\<parallel>r)" and
M4:"\<lbrakk>p\<parallel>q ; q\<parallel>s ; p\<parallel>r ; r\<parallel>s\<rbrakk> \<Longrightarrow> q = r" and
M5exist:"p\<parallel>q \<Longrightarrow> (\<exists>r s t. r\<parallel>p \<and> p\<parallel>q \<and> q\<parallel>s \<and> r\<parallel>t \<and> t\<parallel>s)"
(**********)
lemma (in interval) trans2:"\<lbrakk>p\<parallel>t; t\<parallel>r; r\<parallel>q\<rbrakk> \<Longrightarrow> \<not>p\<parallel>q"
using M1 meets_asym by blast
lemma (in interval) nontrans1: "u\<parallel>r \<Longrightarrow> \<not> (\<exists>t. u\<parallel>t \<and> t\<parallel>r)"
using meets_atrans by blast
lemma (in interval) nontrans2:"u\<parallel>r \<Longrightarrow> \<not> (\<exists>t. r\<parallel>t \<and> t\<parallel>u)"
using M1 M5exist trans2 by blast
lemma (in interval) nonmeets1:"\<not> (u\<parallel>r \<and> r\<parallel>u)"
using meets_asym by blast
lemma (in interval) nonmeets2: "\<lbrakk>\<I> u ; \<I> r \<rbrakk> \<Longrightarrow> \<not> (u\<parallel>r \<and> u = r)"
using meets_irrefl by blast
lemma (in interval) nonmeets3: "\<not> (u\<parallel>r \<and> (\<exists>p. u\<parallel>p \<and> p\<parallel>r))"
using nontrans1 by blast
lemma (in interval) nonmeets4: "\<not>(u\<parallel>r \<and> (\<exists>p. r\<parallel>p \<and> p\<parallel>u))"
using nontrans2 by blast
lemma (in interval) elimmeets: "(p \<parallel> s \<and> (\<exists>t. p \<parallel> t \<and> t \<parallel> s) \<and> (\<exists>t. r \<parallel> t \<and> t \<parallel> q)) = False"
using meets_atrans by blast
lemma (in interval) M5exist_var:
assumes "x\<parallel>y" "y\<parallel>z" "z\<parallel>w"
shows "\<exists>t. x\<parallel>t \<and> t\<parallel>w"
proof -
from assms(1,3) have a:"x\<parallel>w \<oplus> (\<exists>t. x\<parallel>t \<and> t\<parallel>w) \<oplus> (\<exists>t. z\<parallel>t \<and> t\<parallel>y)" using M2[of x y z w] by auto
from assms have b1:"\<not>x\<parallel>w" using trans2 by blast
from assms(2) have "\<not> (\<exists>t. z\<parallel>t \<and> t\<parallel>y)" by (simp add: nontrans2)
with b1 a have " (\<exists>t. x\<parallel>t \<and> t\<parallel>w)" by simp
thus ?thesis by simp
qed
lemma (in interval) M5exist_var2:
assumes "p\<parallel>q"
shows "\<exists>r1 r2 r3 s t. r1\<parallel>r2 \<and> r2\<parallel>r3 \<and> r3\<parallel>p \<and> p\<parallel>q \<and> q\<parallel>s \<and> r1\<parallel>t \<and> t\<parallel>s"
proof -
from assms obtain r3 k1 s where r3p:"r3\<parallel>p" and qs:"q\<parallel>s" and r3k1:"r3 \<parallel>k1" and k1s:"k1\<parallel>s" using M5exist by blast
from r3p obtain r2 where r2r3:"r2\<parallel>r3" using M3[of r3] meets_wd by auto
from r2r3 obtain r1 where r1r2:"r1\<parallel>r2" using M3[of r2] meets_wd by auto
with assms r2r3 r3p qs obtain t where r1t1:"r1\<parallel>t" and t1q:"t\<parallel>s" using M5exist_var by blast
with assms r1r2 r2r3 r3p qs show ?thesis by blast
qed
lemma (in interval) M5exist_var3:
assumes "k\<parallel>l" and "l\<parallel>q" and "q\<parallel>t" and "t\<parallel>r"
shows "\<exists>lqt. k\<parallel>lqt \<and> lqt\<parallel>r"
proof -
from assms(1-3) obtain lq where "k\<parallel>lq" and "lq\<parallel>t"
using M5exist_var by blast
with assms(4) obtain lqt where "k\<parallel>lqt" and "lqt\<parallel>r"
using M5exist_var by blast
thus ?thesis by auto
qed
end
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