wneuper/isa: test/Tools/isac/ADDTESTS/course/SignalProcess/Build_Inverse_Z

neuper@42279	1	(* Title: Test_Z_Transform
neuper@42279	2	Author: Jan Rocnik
neuper@42279	3	(c) copyright due to lincense terms.
neuper@42279	4	12345678901234567890123456789012345678901234567890123456789012345678901234567890
neuper@42279	5	10 20 30 40 50 60 70 80
neuper@42279	6	*)
neuper@42279	7
neuper@42289	8	theory Build_Inverse_Z_Transform imports
neuper@42289	9	Isac "../../../../../../src/Tools/isac/Knowledge/Partial_Fractions"
neuper@42289	10
neuper@42289	11	begin
neuper@42279	12
neuper@42289	13	text{* We stepwise build Inverse_Z_Transform.thy as an exercise.
neuper@42279	14	Because subsection "Stepwise Check the Program" requires Inverse_Z_Transform.thy
neuper@42279	15	as a subtheory of Isac.thy, the setup has been changed from
neuper@42279	16	"theory Inverse_Z_Transform imports Isac begin.." to the above.
neuper@42279	17
neuper@42279	18	ATTENTION WITH NAMES OF IDENTIFIERS WHEN GOING INTO INTERNALS:
neuper@42279	19	Here in this theory there are the internal names twice, for instance we have
neuper@42279	20	(Thm.derivation_name @{thm rule1} = "Build_Inverse_Z_Transform.rule1") = true;
neuper@42279	21	but actually in us will be "Inverse_Z_Transform.rule1"
neuper@42279	22	*}
neuper@42279	23	ML {val thy = @{theory Isac};}
neuper@42279	24
neuper@42279	25
neuper@42279	26	section {trials towards Z transform }
neuper@42279	27	text{===============================}
neuper@42279	28	subsection {terms}
neuper@42279	29	ML {*
neuper@42279	30	@{term "1 < \|\| z \|\|"};
neuper@42279	31	@{term "z / (z - 1)"};
neuper@42279	32	@{term "-u -n - 1"};
neuper@42279	33	@{term "-u [-n - 1]"}; ([ ] denotes lists !!!)
neuper@42279	34	@{term "z /(z - 1) = -u [-n - 1]"};Isac
neuper@42279	35	@{term "1 < \|\| z \|\| ==> z / (z - 1) = -u [-n - 1]"};
neuper@42279	36	term2str @{term "1 < \|\| z \|\| ==> z / (z - 1) = -u [-n - 1]"};
neuper@42279	37	*}
neuper@42279	38	ML {*
neuper@42279	39	(alpha --> "</alpha>" )
neuper@42279	40	@{term "\<alpha> "};
neuper@42279	41	@{term "\<delta> "};
neuper@42279	42	@{term "\<phi> "};
neuper@42279	43	@{term "\<rho> "};
neuper@42279	44	term2str @{term "\<rho> "};
neuper@42279	45	*}
neuper@42279	46
neuper@42279	47	subsection {rules}
neuper@42279	48	(axiomatization "z / (z - 1) = -u [-n - 1]" Illegal variable name: "z / (z - 1) = -u [-n - 1]" )
neuper@42279	49	(definition "z / (z - 1) = -u [-n - 1]" Bad head of lhs: existing constant "op /")
neuper@42279	50	axiomatization where
neuper@42279	51	rule1: "1 = \<delta>[n]" and
neuper@42279	52	rule2: "\|\| z \|\| > 1 ==> z / (z - 1) = u [n]" and
neuper@42279	53	rule3: "\|\| z \|\| < 1 ==> z / (z - 1) = -u [-n - 1]" and
neuper@42279	54	rule4: "\|\| z \|\| > \|\| \<alpha> \|\| ==> z / (z - \<alpha>) = \<alpha>^^^n * u [n]" and
neuper@42279	55	rule5: "\|\| z \|\| < \|\| \<alpha> \|\| ==> z / (z - \<alpha>) = -(\<alpha>^^^n) * u [-n - 1]" and
neuper@42279	56	rule6: "\|\| z \|\| > 1 ==> z/(z - 1)^^^2 = n * u [n]"
neuper@42279	57	ML {*
neuper@42279	58	@{thm rule1};
neuper@42279	59	@{thm rule2};
neuper@42279	60	@{thm rule3};
neuper@42279	61	@{thm rule4};
neuper@42279	62	*}
neuper@42279	63
neuper@42279	64	subsection {apply rules}
neuper@42279	65	ML {*
neuper@42279	66	val inverse_Z = append_rls "inverse_Z" e_rls
neuper@42279	67	[ Thm ("rule3",num_str @{thm rule3}),
neuper@42279	68	Thm ("rule4",num_str @{thm rule4}),
neuper@42279	69	Thm ("rule1",num_str @{thm rule1})
neuper@42279	70	];
neuper@42279	71
neuper@42279	72	val t = str2term "z / (z - 1) + z / (z - \<alpha>) + 1";
neuper@42279	73	val SOME (t', asm) = rewrite_set_ thy true inverse_Z t;
neuper@42279	74	term2str t' = "z / (z - ?\<delta> [?n]) + z / (z - \<alpha>) + ?\<delta> [?n]"; (attention rule1 !!!)
neuper@42279	75	*}
neuper@42279	76	ML {*
neuper@42279	77	val (thy, ro, er) = (@{theory Isac}, tless_true, eval_rls);
neuper@42279	78	*}
neuper@42279	79	ML {*
neuper@42279	80	val SOME (t, asm1) = rewrite_ thy ro er true (num_str @{thm rule3}) t;
neuper@42279	81	term2str t = "- ?u [- ?n - 1] + z / (z - \<alpha>) + 1"; (- real )
neuper@42279	82	term2str t;
neuper@42279	83	*}
neuper@42279	84	ML {*
neuper@42279	85	val SOME (t, asm2) = rewrite_ thy ro er true (num_str @{thm rule4}) t;
neuper@42279	86	term2str t = "- ?u [- ?n - 1] + \<alpha> ^^^ ?n * ?u [?n] + 1"; (- real )
neuper@42279	87	term2str t;
neuper@42279	88	*}
neuper@42279	89	ML {*
neuper@42279	90	val SOME (t, asm3) = rewrite_ thy ro er true (num_str @{thm rule1}) t;
neuper@42279	91	term2str t = "- ?u [- ?n - 1] + \<alpha> ^^^ ?n * ?u [?n] + ?\<delta> [?n]"; (- real )
neuper@42279	92	term2str t;
neuper@42279	93	*}
neuper@42279	94	ML {*
neuper@42279	95	terms2str (asm1 @ asm2 @ asm3);
neuper@42279	96	*}
neuper@42279	97
jan@42296	98	section {Prepare steps for CTP-based programming language}
jan@42296	99	text{*TODO insert Calculation (Referenz?!)
jan@42296	100
jan@42296	101	The goal... realized in sections below, in Sect.\ref{spec-meth} and Sect.\ref{prog-steps}
jan@42296	102
jan@42296	103	the reader is advised to jump between the subsequent subsections and the respective steps in Sect.\ref{prog-steps}
jan@42296	104
jan@42296	105	*}
jan@42296	106	subsection {prepare expression \label{prep-expr}}
neuper@42279	107	ML {*
neuper@42279	108	val ctxt = ProofContext.init_global @{theory Isac};
neuper@42279	109	val ctxt = declare_constraints' [@{term "z::real"}] ctxt;
neuper@42279	110
neuper@42279	111	val SOME fun1 = parseNEW ctxt "X z = 3 / (z - 1/4 + -1/8 * z ^^^ -1)"; term2str fun1;
neuper@42279	112	val SOME fun1' = parseNEW ctxt "X z = 3 / (z - 1/4 + -1/8 * (1/z))"; term2str fun1';
neuper@42279	113	*}
neuper@42279	114
neuper@42279	115	axiomatization where
neuper@42279	116	ruleZY: "(X z = a / b) = (X' z = a / (z * b))"
neuper@42279	117
neuper@42279	118	ML {*
neuper@42279	119	val (thy, ro, er) = (@{theory Isac}, tless_true, eval_rls);
neuper@42279	120	val SOME (fun2, asm1) = rewrite_ thy ro er true @{thm ruleZY} fun1; term2str fun2;
neuper@42279	121	val SOME (fun2', asm1) = rewrite_ thy ro er true @{thm ruleZY} fun1'; term2str fun2';
neuper@42279	122
neuper@42279	123	val SOME (fun3,_) = rewrite_set_ @{theory Isac} false norm_Rational fun2;
neuper@42279	124	term2str fun3; (fails on x^^^(-1) TODO)
neuper@42279	125	val SOME (fun3',_) = rewrite_set_ @{theory Isac} false norm_Rational fun2';
neuper@42279	126	term2str fun3'; (OK)
neuper@42289	127	*}
neuper@42279	128
neuper@42289	129	subsection {build equation from given term}
neuper@42289	130	ML {*
neuper@42279	131	val (_, expr) = HOLogic.dest_eq fun3'; term2str expr;
neuper@42289	132	val (_, denom) = HOLogic.dest_bin "Rings.inverse_class.divide" (type_of expr) expr;
neuper@42289	133	term2str denom = "-1 + -2 * z + 8 * z ^^^ 2";
neuper@42279	134	*}
neuper@42289	135	text {*we have rhs in the language, but we need a function
neuper@42289	136	which gets the denominator of a fraction*}
neuper@42289	137	ML {*
neuper@42290	138	(GOON ===================================================)
neuper@42289	139
neuper@42289	140	*}
neuper@42289	141	ML {*
neuper@42289	142	*}
neuper@42289	143	ML {**}
neuper@42279	144
neuper@42279	145	subsection {solve equation}
neuper@42279	146	text {this type of equation if too general for the present program}
neuper@42279	147	ML {*
neuper@42279	148	"----------- Minisubplb/100-init-rootp (OK)bl.sml ---------------------";
neuper@42279	149	val denominator = parseNEW ctxt "z^^^2 - 1/4*z - 1/8 = 0";
neuper@42279	150	val fmz = ["equality (z^^^2 - 1/4*z - 1/8 = (0::real))", "solveFor z","solutions L"];
neuper@42279	151	val (dI',pI',mI') =("Isac", ["univariate","equation"], ["no_met"]);
neuper@42279	152	(* ^^^^^^^^^^^^^^^^^^^^^^ TODO: ISAC determines type of eq*)
neuper@42279	153	*}
neuper@42279	154	text {Does the Equation Match the Specification ?}
neuper@42279	155	ML {*
neuper@42279	156	match_pbl fmz (get_pbt ["univariate","equation"]);
neuper@42279	157	*}
neuper@42279	158	ML {Context.theory_name thy = "Isac"(==================================================)}
neuper@42279	159
neuper@42279	160	ML {*
neuper@42279	161	val denominator = parseNEW ctxt "-1/8 + -1/4*z + z^^^2 = 0";
neuper@42279	162	val fmz = (specification)
neuper@42279	163	["equality (-1/8 + (-1/4)z + z^^^2 = (0::real))", (equality*)
neuper@42279	164	"solveFor z", (bound variable)
neuper@42279	165	"solutions L"]; (identifier for solution)
neuper@42279	166	(liste der theoreme die zum lösen benötigt werden, aus isac, keine spezielle methode (no met))
neuper@42279	167	val (dI',pI',mI') =
neuper@42279	168	("Isac", ["pqFormula","degree_2","polynomial","univariate","equation"], ["no_met"]);
neuper@42279	169	*}
neuper@42279	170	text {Does the Other Equation Match the Specification ?}
neuper@42279	171	ML {*
neuper@42279	172	match_pbl fmz (get_pbt ["pqFormula","degree_2","polynomial","univariate","equation"]);
neuper@42279	173	*}
neuper@42279	174	text {Solve Equation Stepwise}
neuper@42279	175	ML {*
neuper@42279	176	val (p,_,f,nxt,_,pt) = CalcTreeTEST [(fmz, (dI',pI',mI'))];
neuper@42279	177	val (p,_,f,nxt,_,pt) = me nxt p [] pt;
neuper@42279	178	val (p,_,f,nxt,_,pt) = me nxt p [] pt;
neuper@42279	179	val (p,_,f,nxt,_,pt) = me nxt p [] pt;
neuper@42279	180	val (p,_,f,nxt,_,pt) = me nxt p [] pt;
neuper@42279	181	val (p,_,f,nxt,_,pt) = me nxt p [] pt;
neuper@42279	182	val (p,_,f,nxt,_,pt) = me nxt p [] pt;
neuper@42279	183	val (p,_,f,nxt,_,pt) = me nxt p [] pt;
neuper@42279	184	val (p,_,f,nxt,_,pt) = me nxt p [] pt;
neuper@42279	185	val (p,_,f,nxt,_,pt) = me nxt p [] pt;
neuper@42279	186	val (p,_,f,nxt,_,pt) = me nxt p [] pt;
neuper@42279	187	val (p,_,f,nxt,_,pt) = me nxt p [] pt;
neuper@42279	188	val (p,_,f,nxt,_,pt) = me nxt p [] pt; (nxt =..,Check_elementwise "Assumptions"))
neuper@42279	189	val (p,_,f,nxt,_,pt) = me nxt p [] pt;
neuper@42279	190	val (p,_,f,nxt,_,pt) = me nxt p [] pt; f2str f;
neuper@42279	191	([z = 1 / 8 + sqrt (9 / 16) / 2, z = 1 / 8 + -1 sqrt (9 / 16) / 2] TODO sqrt*)
neuper@42279	192	show_pt pt;
neuper@42279	193	val SOME f = parseNEW ctxt "[z=1/2, z=-1/4]";
neuper@42279	194	*}
neuper@42279	195
neuper@42279	196	subsection {partial fraction decomposition}
neuper@42279	197	subsubsection {solution of the equation}
neuper@42279	198	ML {*
neuper@42279	199	val SOME solutions = parseNEW ctxt "[z=1/2, z=-1/4]";
neuper@42279	200	term2str solutions;
neuper@42279	201	atomty solutions;
neuper@42279	202	*}
neuper@42279	203
neuper@42279	204	subsubsection {get solutions out of list}
neuper@42279	205	text {in isac's CTP-based programming language: let$ $s_1 = NTH 1$ solutions; $s_2 = NTH 2...$}
neuper@42279	206	ML {*
neuper@42279	207	val Const ("List.list.Cons", _) $ s_1 $ (Const ("List.list.Cons", _) $
neuper@42279	208	s_2 $ Const ("List.list.Nil", _)) = solutions;
neuper@42279	209	term2str s_1;
neuper@42279	210	term2str s_2;
neuper@42279	211	*}
neuper@42279	212
neuper@42279	213	ML {* (Solutions as Denominator --> Denominator1 = z - Zeropoint1, Denominator2 = z-Zeropoint2,...)
neuper@42279	214	val xx = HOLogic.dest_eq s_1;
neuper@42279	215	val s_1' = HOLogic.mk_binop "Groups.minus_class.minus" xx;
neuper@42279	216	val xx = HOLogic.dest_eq s_2;
neuper@42279	217	val s_2' = HOLogic.mk_binop "Groups.minus_class.minus" xx;
neuper@42279	218	term2str s_1';
neuper@42279	219	term2str s_2';
neuper@42279	220	*}
neuper@42279	221
neuper@42279	222	subsubsection {build expression}
neuper@42279	223	text {in isac's CTP-based programming language: let s_1 = Take numerator / (s_1 s_2)*}
neuper@42279	224	ML {*
neuper@42279	225	(The Main Denominator is the multiplikation of the partial fraction denominators)
neuper@42279	226	val denominator' = HOLogic.mk_binop "Groups.times_class.times" (s_1', s_2') ;
neuper@42279	227	val SOME numerator = parseNEW ctxt "3::real";
neuper@42279	228
neuper@42279	229	val expr' = HOLogic.mk_binop "Rings.inverse_class.divide" (numerator, denominator');
neuper@42279	230	term2str expr';
neuper@42279	231	*}
neuper@42279	232
neuper@42279	233	subsubsection {Ansatz - create partial fractions out of our expression}
neuper@42279	234	ML {Context.theory_name thy = "Isac"(==================================================)}
neuper@42279	235
neuper@42279	236	axiomatization where
neuper@42279	237	ansatz2: "n / (a*b) = A/a + B/(b::real)" and
neuper@42279	238	multiply_eq2: "(n / (ab) = A/a + B/b) = (ab(n / (ab)) = ab(A/a + B/b))"
neuper@42279	239
neuper@42279	240	ML {*
neuper@42279	241	(we use our ansatz2 to rewrite our expression and get an equilation with our expression on the left and the partial fractions of it on the right side)
neuper@42279	242	val SOME (t1,_) = rewrite_ @{theory Isac} e_rew_ord e_rls false @{thm ansatz2} expr';
neuper@42279	243	term2str t1; atomty t1;
neuper@42279	244	val eq1 = HOLogic.mk_eq (expr', t1);
neuper@42279	245	term2str eq1;
neuper@42279	246	*}
neuper@42279	247	ML {*
neuper@42279	248	(eliminate the demoninators by multiplying the left and the right side with the main denominator)
neuper@42279	249	val SOME (eq2,_) = rewrite_ @{theory Isac} e_rew_ord e_rls false @{thm multiply_eq2} eq1;
neuper@42279	250	term2str eq2;
neuper@42279	251	*}
neuper@42279	252	ML {*
neuper@42279	253	(simplificatoin)
neuper@42279	254	val SOME (eq3,_) = rewrite_set_ @{theory Isac} false norm_Rational eq2;
neuper@42279	255	term2str eq3; (?A ?B not simplified)
neuper@42279	256	*}
neuper@42279	257	ML {*
neuper@42279	258	val SOME fract1 =
neuper@42279	259	parseNEW ctxt "(z - 1 / 2) * (z - -1 / 4) * (A / (z - 1 / 2) + B / (z - -1 / 4))"; (A B !)
neuper@42279	260	val SOME (fract2,_) = rewrite_set_ @{theory Isac} false norm_Rational fract1;
neuper@42279	261	term2str fract2 = "(A + -2 * B + 4 * A * z + 4 * B * z) / 4";
neuper@42279	262	(term2str fract2 = "A (1 / 4 + z) + B * (-1 / 2 + z)" would be more traditional*)
neuper@42279	263	*}
neuper@42279	264	ML {*
neuper@42279	265	val (numerator, denominator) = HOLogic.dest_eq eq3;
neuper@42279	266	val eq3' = HOLogic.mk_eq (numerator, fract1); (A B !)
neuper@42279	267	term2str eq3';
neuper@42279	268	(MANDATORY: simplify (and remove denominator) otherwise 3 = 0)
neuper@42279	269	val SOME (eq3'' ,_) = rewrite_set_ @{theory Isac} false norm_Rational eq3';
neuper@42279	270	term2str eq3'';
neuper@42279	271	*}
neuper@42279	272	ML {Context.theory_name thy = "Isac"(==================================================)}
neuper@42279	273
neuper@42279	274	subsubsection {get first koeffizient}
neuper@42279	275
neuper@42279	276	ML {*
neuper@42279	277	(substitude z with the first zeropoint to get A)
neuper@42279	278	val SOME (eq4_1,_) = rewrite_terms_ @{theory Isac} e_rew_ord e_rls [s_1] eq3'';
neuper@42279	279	term2str eq4_1;
neuper@42279	280
neuper@42279	281	val SOME (eq4_2,_) = rewrite_set_ @{theory Isac} false norm_Rational eq4_1;
neuper@42279	282	term2str eq4_2;
neuper@42279	283
neuper@42279	284	val fmz = ["equality (3 = 3 * A / (4::real))", "solveFor A","solutions L"];
neuper@42279	285	val (dI',pI',mI') =("Isac", ["univariate","equation"], ["no_met"]);
neuper@42279	286	(solve the simple linear equilation for A TODO: return eq, not list of eq)
neuper@42279	287	val (p,_,fa,nxt,_,pt) = CalcTreeTEST [(fmz, (dI',pI',mI'))];
neuper@42279	288	val (p,_,fa,nxt,_,pt) = me nxt p [] pt;
neuper@42279	289	val (p,_,fa,nxt,_,pt) = me nxt p [] pt;
neuper@42279	290	val (p,_,fa,nxt,_,pt) = me nxt p [] pt;
neuper@42279	291	val (p,_,fa,nxt,_,pt) = me nxt p [] pt;
neuper@42279	292	val (p,_,fa,nxt,_,pt) = me nxt p [] pt;
neuper@42279	293	val (p,_,fa,nxt,_,pt) = me nxt p [] pt;
neuper@42279	294	val (p,_,fa,nxt,_,pt) = me nxt p [] pt;
neuper@42279	295	val (p,_,fa,nxt,_,pt) = me nxt p [] pt;
neuper@42279	296	val (p,_,fa,nxt,_,pt) = me nxt p [] pt;
neuper@42279	297	val (p,_,fa,nxt,_,pt) = me nxt p [] pt;
neuper@42279	298	val (p,_,fa,nxt,_,pt) = me nxt p [] pt;
neuper@42279	299	val (p,_,fa,nxt,_,pt) = me nxt p [] pt;
neuper@42279	300	val (p,_,fa,nxt,_,pt) = me nxt p [] pt;
neuper@42279	301	val (p,_,fa,nxt,_,pt) = me nxt p [] pt;
neuper@42279	302	val (p,_,fa,nxt,_,pt) = me nxt p [] pt;
neuper@42279	303	val (p,_,fa,nxt,_,pt) = me nxt p [] pt;
neuper@42279	304	val (p,_,fa,nxt,_,pt) = me nxt p [] pt;
neuper@42279	305	val (p,_,fa,nxt,_,pt) = me nxt p [] pt;
neuper@42279	306	val (p,_,fa,nxt,_,pt) = me nxt p [] pt;
neuper@42279	307	val (p,_,fa,nxt,_,pt) = me nxt p [] pt;
neuper@42279	308	val (p,_,fa,nxt,_,pt) = me nxt p [] pt;
neuper@42279	309	val (p,_,fa,nxt,_,pt) = me nxt p [] pt;
neuper@42279	310	val (p,_,fa,nxt,_,pt) = me nxt p [] pt;
neuper@42279	311	val (p,_,fa,nxt,_,pt) = me nxt p [] pt;
neuper@42279	312	val (p,_,fa,nxt,_,pt) = me nxt p [] pt;
neuper@42279	313	val (p,_,fa,nxt,_,pt) = me nxt p [] pt;
neuper@42279	314	val (p,_,fa,nxt,_,pt) = me nxt p [] pt;
neuper@42279	315	f2str fa;
neuper@42279	316	*}
neuper@42279	317
neuper@42279	318	subsubsection {get second koeffizient}
neuper@42279	319	ML {thy}
neuper@42279	320
neuper@42279	321	ML {*
neuper@42279	322	(substitude z with the second zeropoint to get B)
neuper@42279	323	val SOME (eq4b_1,_) = rewrite_terms_ @{theory Isac} e_rew_ord e_rls [s_2] eq3'';
neuper@42279	324	term2str eq4b_1;
neuper@42279	325
neuper@42279	326	val SOME (eq4b_2,_) = rewrite_set_ @{theory Isac} false norm_Rational eq4b_1;
neuper@42279	327	term2str eq4b_2;
neuper@42279	328	*}
neuper@42279	329	ML {*
neuper@42279	330	(solve the simple linear equilation for B TODO: return eq, not list of eq)
neuper@42279	331	val fmz = ["equality (3 = -3 * B / (4::real))", "solveFor B","solutions L"];
neuper@42279	332	val (dI',pI',mI') =("Isac", ["univariate","equation"], ["no_met"]);
neuper@42279	333	val (p,_,fb,nxt,_,pt) = CalcTreeTEST [(fmz, (dI',pI',mI'))];
neuper@42279	334	val (p,_,fb,nxt,_,pt) = me nxt p [] pt;
neuper@42279	335	val (p,_,fb,nxt,_,pt) = me nxt p [] pt;
neuper@42279	336	val (p,_,fb,nxt,_,pt) = me nxt p [] pt;
neuper@42279	337	val (p,_,fb,nxt,_,pt) = me nxt p [] pt;
neuper@42279	338	val (p,_,fb,nxt,_,pt) = me nxt p [] pt;
neuper@42279	339	val (p,_,fb,nxt,_,pt) = me nxt p [] pt;
neuper@42279	340	val (p,_,fb,nxt,_,pt) = me nxt p [] pt;
neuper@42279	341	val (p,_,fb,nxt,_,pt) = me nxt p [] pt;
neuper@42279	342	val (p,_,fb,nxt,_,pt) = me nxt p [] pt;
neuper@42279	343	val (p,_,fb,nxt,_,pt) = me nxt p [] pt;
neuper@42279	344	val (p,_,fb,nxt,_,pt) = me nxt p [] pt;
neuper@42279	345	val (p,_,fb,nxt,_,pt) = me nxt p [] pt;
neuper@42279	346	val (p,_,fb,nxt,_,pt) = me nxt p [] pt;
neuper@42279	347	val (p,_,fb,nxt,_,pt) = me nxt p [] pt;
neuper@42279	348	val (p,_,fb,nxt,_,pt) = me nxt p [] pt;
neuper@42279	349	val (p,_,fb,nxt,_,pt) = me nxt p [] pt;
neuper@42279	350	val (p,_,fb,nxt,_,pt) = me nxt p [] pt;
neuper@42279	351	val (p,_,fb,nxt,_,pt) = me nxt p [] pt;
neuper@42279	352	val (p,_,fb,nxt,_,pt) = me nxt p [] pt;
neuper@42279	353	val (p,_,fb,nxt,_,pt) = me nxt p [] pt;
neuper@42279	354	val (p,_,fb,nxt,_,pt) = me nxt p [] pt;
neuper@42279	355	val (p,_,fb,nxt,_,pt) = me nxt p [] pt;
neuper@42279	356	val (p,_,fb,nxt,_,pt) = me nxt p [] pt;
neuper@42279	357	val (p,_,fb,nxt,_,pt) = me nxt p [] pt;
neuper@42279	358	val (p,_,fb,nxt,_,pt) = me nxt p [] pt;
neuper@42279	359	val (p,_,fb,nxt,_,pt) = me nxt p [] pt;
neuper@42279	360	val (p,_,fb,nxt,_,pt) = me nxt p [] pt;
neuper@42279	361	f2str fb;
neuper@42279	362	*}
neuper@42279	363
neuper@42279	364	ML {* (check koeffizients)
neuper@42279	365	if f2str fa = "[A = 4]" then () else error "part.fract. eq4_1";
neuper@42279	366	if f2str fb = "[B = -4]" then () else error "part.fract. eq4_1";
neuper@42279	367	*}
neuper@42279	368
neuper@42279	369	subsubsection {substitute expression with solutions}
neuper@42279	370	ML {*
neuper@42279	371	*}
neuper@42279	372	ML {thy}
neuper@42279	373
jan@42296	374	section {Implement the Specification and the Method \label{spec-meth}}
neuper@42279	375	text{==============================================}
neuper@42279	376	subsection{Define the Field Descriptions for the specification}
neuper@42279	377	consts
neuper@42279	378	filterExpression :: "bool => una"
neuper@42279	379	stepResponse :: "bool => una"
neuper@42279	380
neuper@42279	381	subsection{Define the Specification}
neuper@42279	382	ML {*
neuper@42279	383	store_pbt
neuper@42279	384	(prep_pbt thy "pbl_SP" [] e_pblID
neuper@42279	385	(["SignalProcessing"], [], e_rls, NONE, []));
neuper@42279	386	store_pbt
neuper@42279	387	(prep_pbt thy "pbl_SP_Ztrans" [] e_pblID
neuper@42279	388	(["Z_Transform","SignalProcessing"], [], e_rls, NONE, []));
neuper@42279	389	*}
neuper@42279	390	ML {thy}
neuper@42279	391	ML {*
neuper@42279	392	store_pbt
neuper@42279	393	(prep_pbt thy "pbl_SP_Ztrans_inv" [] e_pblID
neuper@42279	394	(["inverse", "Z_Transform", "SignalProcessing"],
neuper@42279	395	[("#Given" ,["filterExpression X_eq"]),
neuper@42279	396	("#Find" ,["stepResponse n_eq"])
neuper@42279	397	],
neuper@42279	398	append_rls "e_rls" e_rls [(for preds in where_)], NONE,
neuper@42279	399	[["SignalProcessing","Z_Transform","inverse"]]));
neuper@42279	400
neuper@42279	401	show_ptyps();
neuper@42279	402	get_pbt ["inverse","Z_Transform","SignalProcessing"];
neuper@42279	403	*}
neuper@42279	404
neuper@42279	405	subsection {Define Name and Signature for the Method}
neuper@42279	406	consts
neuper@42279	407	InverseZTransform :: "[bool, bool] => bool"
neuper@42279	408	("((Script InverseZTransform (_ =))// (_))" 9)
neuper@42279	409
neuper@42279	410	subsection {Setup Parent Nodes in Hierarchy of Method}
neuper@42279	411	ML {*
neuper@42279	412	store_met
neuper@42279	413	(prep_met thy "met_SP" [] e_metID
neuper@42279	414	(["SignalProcessing"], [],
neuper@42279	415	{rew_ord'="tless_true", rls'= e_rls, calc = [], srls = e_rls, prls = e_rls,
neuper@42279	416	crls = e_rls, nrls = e_rls}, "empty_script"));
neuper@42279	417	store_met
neuper@42279	418	(prep_met thy "met_SP_Ztrans" [] e_metID
neuper@42279	419	(["SignalProcessing", "Z_Transform"], [],
neuper@42279	420	{rew_ord'="tless_true", rls'= e_rls, calc = [], srls = e_rls, prls = e_rls,
neuper@42279	421	crls = e_rls, nrls = e_rls}, "empty_script"));
neuper@42279	422	*}
neuper@42279	423	ML {*
neuper@42279	424	store_met
neuper@42279	425	(prep_met thy "met_SP_Ztrans_inv" [] e_metID
neuper@42279	426	(["SignalProcessing", "Z_Transform", "inverse"],
neuper@42279	427	[("#Given" ,["filterExpression X_eq"]),
neuper@42279	428	("#Find" ,["stepResponse n_eq"])
neuper@42279	429	],
neuper@42279	430	{rew_ord'="tless_true", rls'= e_rls, calc = [], srls = e_rls, prls = e_rls,
neuper@42279	431	crls = e_rls, nrls = e_rls},
neuper@42279	432	"empty_script"
neuper@42279	433	));
neuper@42279	434	*}
neuper@42279	435	ML {*
neuper@42279	436	store_met
neuper@42279	437	(prep_met thy "met_SP_Ztrans_inv" [] e_metID
neuper@42279	438	(["SignalProcessing", "Z_Transform", "inverse"],
neuper@42279	439	[("#Given" ,["filterExpression X_eq"]),
neuper@42279	440	("#Find" ,["stepResponse n_eq"])
neuper@42279	441	],
neuper@42279	442	{rew_ord'="tless_true", rls'= e_rls, calc = [], srls = e_rls, prls = e_rls,
neuper@42279	443	crls = e_rls, nrls = e_rls},
neuper@42279	444	"Script InverseZTransform (Xeq::bool) =" ^
neuper@42279	445	" (let X = Take Xeq;" ^
neuper@42279	446	" X = Rewrite ruleZY False X" ^
neuper@42279	447	" in X)"
neuper@42279	448	));
neuper@42279	449
neuper@42279	450	show_mets();
neuper@42279	451	get_met ["SignalProcessing","Z_Transform","inverse"];
neuper@42279	452	*}
neuper@42279	453
jan@42296	454	section {Program in CTP-based language \label{prog-steps}}
neuper@42279	455	text{=================================}
neuper@42279	456	subsection {Stepwise extend Program}
neuper@42279	457	ML {*
neuper@42279	458	val str =
neuper@42279	459	"Script InverseZTransform (Xeq::bool) =" ^
neuper@42279	460	" Xeq";
neuper@42279	461	*}
neuper@42279	462	ML {*
neuper@42279	463	val str =
neuper@42279	464	"Script InverseZTransform (Xeq::bool) =" ^ ((1/z) instead of z ^^^ -1)
neuper@42279	465	" (let X = Take Xeq;" ^
neuper@42279	466	" X' = Rewrite ruleZY False X;" ^ (z denominator*)
neuper@42279	467	" X' = (Rewrite_Set norm_Rational False) X'" ^ (simplify)
neuper@42279	468	" in X)";
neuper@42279	469	(NONE)
neuper@42279	470	"Script InverseZTransform (Xeq::bool) =" ^ ((1/z) instead of z ^^^ -1)
neuper@42279	471	" (let X = Take Xeq;" ^
neuper@42279	472	" X' = Rewrite ruleZY False X;" ^ (z denominator*)
neuper@42279	473	" X' = (Rewrite_Set norm_Rational False) X';" ^ (simplify)
neuper@42279	474	" X' = (SubProblem (Isac',[pqFormula,degree_2,polynomial,univariate,equation], [no_met]) " ^
neuper@42279	475	" [BOOL e_e, REAL v_v])" ^
neuper@42279	476	" in X)";
neuper@42279	477	*}
neuper@42279	478	ML {*
neuper@42279	479	val str =
neuper@42279	480	"Script InverseZTransform (Xeq::bool) =" ^ ((1/z) instead of z ^^^ -1)
neuper@42279	481	" (let X = Take Xeq;" ^
neuper@42279	482	" X' = Rewrite ruleZY False X;" ^ (z denominator*)
neuper@42279	483	" X' = (Rewrite_Set norm_Rational False) X';" ^ (simplify)
neuper@42279	484	" funterm = rhs X'" ^ (drop X'= for equation solving)
neuper@42279	485	" in X)";
neuper@42279	486	*}
neuper@42279	487	ML {*
neuper@42290	488	val str =
neuper@42290	489	"Script InverseZTransform (X_eq::bool) =" ^ ((1/z) instead of z ^^^ -1)
neuper@42290	490	" (let X = Take X_eq;" ^
neuper@42290	491	" X' = Rewrite ruleZY False X;" ^ (z denominator*)
neuper@42290	492	" X' = (Rewrite_Set norm_Rational False) X';" ^ (simplify)
neuper@42290	493	" funterm = Take (rhs X');" ^ (drop X' z = for equation solving)
neuper@42290	494	" denom = (Rewrite_Set partial_fraction False) funterm;" ^ (get_denominator)
neuper@42290	495	" equ = (denom = (0::real));" ^
neuper@42290	496	" fun_arg = Take (lhs X');" ^
neuper@42290	497	" arg = (Rewrite_Set partial_fraction False) X';" ^ (get_argument TODO)
neuper@42290	498	" (L_L::bool list) = " ^
neuper@42290	499	" (SubProblem (Test', " ^
neuper@42290	500	" [linear,univariate,equation,test]," ^
neuper@42290	501	" [Test,solve_linear]) " ^
neuper@42290	502	" [BOOL equ, REAL z]) " ^
neuper@42290	503	" in X)"
neuper@42290	504	;
neuper@42290	505
neuper@42279	506	parse thy str;
neuper@42279	507	val sc = ((inst_abs thy) o term_of o the o (parse thy)) str;
neuper@42279	508	atomty sc;
neuper@42279	509
neuper@42279	510	*}
neuper@42279	511	ML {*
neuper@42290	512	val srls = Rls {id="srls_InverseZTransform",
neuper@42290	513	preconds = [], rew_ord = ("termlessI",termlessI),
neuper@42290	514	erls = append_rls "erls_in_srls_InverseZTransform" e_rls
neuper@42290	515	[(for asm in NTH_CONS ...) Calc ("Orderings.ord_class.less",eval_equ "#less_"),
neuper@42290	516	(2nd NTH_CONS pushes n+-1 into asms) Calc("Groups.plus_class.plus", eval_binop "#add_")
neuper@42290	517	],
neuper@42290	518	srls = Erls, calc = [],
neuper@42290	519	rules =
neuper@42290	520	[Thm ("NTH_CONS",num_str @{thm NTH_CONS}),
neuper@42290	521	Calc("Groups.plus_class.plus", eval_binop "#add_"),
neuper@42290	522	Thm ("NTH_NIL",num_str @{thm NTH_NIL}),
neuper@42290	523	Calc("Tools.lhs", eval_lhs"eval_lhs_"), (<=== ONLY USED)
neuper@42290	524	Calc("Tools.rhs", eval_rhs"eval_rhs_"), (<=== ONLY USED)
neuper@42290	525	Calc("Atools.argument'_in", eval_argument_in "Atools.argument'_in")
neuper@42290	526	],
neuper@42290	527	scr = EmptyScr};
neuper@42279	528	*}
neuper@42279	529
neuper@42279	530
neuper@42279	531	subsection {Store Final Version of Program for Execution}
neuper@42279	532	ML {*
neuper@42279	533	store_met
neuper@42279	534	(prep_met thy "met_SP_Ztrans_inv" [] e_metID
neuper@42279	535	(["SignalProcessing", "Z_Transform", "inverse"],
neuper@42279	536	[("#Given" ,["filterExpression X_eq"]),
neuper@42279	537	("#Find" ,["stepResponse n_eq"])
neuper@42279	538	],
neuper@42290	539	{rew_ord'="tless_true", rls'= e_rls, calc = [], srls = srls,
neuper@42290	540	prls = e_rls,
neuper@42279	541	crls = e_rls, nrls = e_rls},
neuper@42289	542	"Script InverseZTransform (X_eq::bool) =" ^ ((1/z) instead of z ^^^ -1)
neuper@42289	543	" (let X = Take X_eq;" ^
neuper@42279	544	" X' = Rewrite ruleZY False X;" ^ (z denominator*)
neuper@42279	545	" X' = (Rewrite_Set norm_Rational False) X';" ^ (simplify)
neuper@42290	546	" funterm = Take (rhs X');" ^ (drop X' z = for equation solving)
neuper@42290	547	" denom = (Rewrite_Set partial_fraction False) funterm;" ^ (get_denominator)
neuper@42290	548	" equ = (denom = (0::real));" ^
neuper@42290	549	" fun_arg = Take (lhs X');" ^ (= get_argument (lhs X'))
neuper@42290	550	" arg = (Rewrite_Set partial_fraction False) X';" ^ (get_argument TODO)
neuper@42290	551	" (L_L::bool list) = " ^
neuper@42290	552	" (SubProblem (Test', " ^
neuper@42290	553	" [linear,univariate,equation,test]," ^
neuper@42290	554	" [Test,solve_linear]) " ^
neuper@42290	555	" [BOOL equ, REAL z]) " ^
neuper@42279	556	" in X)"
neuper@42279	557	));
neuper@42279	558	*}
neuper@42290	559	ML {*
neuper@42290	560	(GOON tip for eval_get_argument: compare eval_get_denominator)
neuper@42290	561	val funId $ arg = @{term "X (z::real)"};
neuper@42279	562
neuper@42290	563	*}
neuper@42279	564
neuper@42281	565	subsection {Check the Program}
neuper@42279	566
neuper@42281	567	subsubsection {Check the formalization}
neuper@42279	568	ML {*
neuper@42279	569	val fmz = ["filterExpression (X = 3 / (z - 1/4 + -1/8 * (1/(z::real))))",
neuper@42279	570	"stepResponse (x[n::real]::bool)"];
neuper@42279	571	val (dI,pI,mI) = ("Isac", ["inverse", "Z_Transform", "SignalProcessing"],
neuper@42279	572	["SignalProcessing","Z_Transform","inverse"]);
neuper@42281	573
neuper@42281	574	val ([(1, [1], "#Given", Const ("Inverse_Z_Transform.filterExpression", _),
neuper@42281	575	[Const ("HOL.eq", _) $ _ $ _]),
neuper@42281	576	(2, [1], "#Find", Const ("Inverse_Z_Transform.stepResponse", _),
neuper@42281	577	[Free ("x", _) $ _])],
neuper@42281	578	_) = prep_ori fmz thy ((#ppc o get_pbt) pI);
neuper@42281	579	*}
neuper@42290	580	ML {*
neuper@42290	581	val Script sc = (#scr o get_met) ["SignalProcessing","Z_Transform","inverse"];
neuper@42290	582	atomty sc;
neuper@42290	583	*}
neuper@42281	584
neuper@42281	585	subsubsection {Stepwise check the program}
neuper@42281	586	ML {*
jan@42296	587	trace_script := false; print_depth 999;
neuper@42281	588	val fmz = ["filterExpression (X z = 3 / (z - 1/4 + -1/8 * (1/(z::real))))",
neuper@42281	589	"stepResponse (x[n::real]::bool)"];
neuper@42281	590	val (dI,pI,mI) = ("Isac", ["inverse", "Z_Transform", "SignalProcessing"],
neuper@42281	591	["SignalProcessing","Z_Transform","inverse"]);
jan@42296	592	val (p,_,f,nxt,_,pt) = CalcTreeTEST [(fmz, (dI,pI,mI))];
jan@42296	593	val (p,_,f,nxt,_,pt) = me nxt p [] pt;
jan@42296	594	val (p,_,f,nxt,_,pt) = me nxt p [] pt;
jan@42296	595	val (p,_,f,nxt,_,pt) = me nxt p [] pt;
jan@42296	596	val (p,_,f,nxt,_,pt) = me nxt p [] pt;
jan@42296	597	val (p,_,f,nxt,_,pt) = me nxt p [] pt;
jan@42296	598	val (p,_,f,nxt,_,pt) = me nxt p [] pt; "nxt = Apply_Method";
jan@42296	599	val (p,_,f,nxt,_,pt) = me nxt p [] pt; "nxt = Rewrite (ruleZY, Inverse_Z_Transform.ruleZY) --> X z = 3 / (z - 1 / 4 + -1 / 8 * (1 / z))";
jan@42296	600	val (p,_,f,nxt,_,pt) = me nxt p [] pt; "nxt = Rewrite_Set norm_Rational --> X' z = 3 / (z * (z - 1 / 4 + -1 / 8 * (1 / z)))";
jan@42296	601	val (p,_,f,nxt,_,pt) = me nxt p [] pt; "nxt = Take 24 / (-1 + -2 * z + 8 * z ^^^ 2)";
jan@42296	602	val (p,_,f,nxt,_,pt) = me nxt p [] pt; " Empty_Tac! ";
neuper@42279	603	*}
neuper@42279	604	ML {*
neuper@42289	605	show_pt pt;
neuper@42279	606	*}
neuper@42279	607	ML {*
neuper@42279	608	*}
neuper@42279	609	ML {*
neuper@42279	610
neuper@42279	611	*}
neuper@42279	612	ML {*
neuper@42279	613
neuper@42279	614	*}
neuper@42279	615	ML {*
neuper@42279	616
neuper@42279	617	*}
neuper@42279	618	ML {*
neuper@42279	619
neuper@42279	620	*}
neuper@42279	621
neuper@42279	622	ML {*
neuper@42279	623
neuper@42279	624	*}
neuper@42279	625	ML {*
neuper@42290	626	@{theory Isac}
neuper@42279	627	*}
neuper@42279	628
neuper@42279	629	ML {*
neuper@42279	630	*}
neuper@42279	631	ML {*
neuper@42279	632	*}
neuper@42279	633	ML {*
neuper@42279	634	*}
neuper@42279	635
neuper@42279	636
neuper@42279	637
neuper@42279	638
neuper@42279	639
neuper@42279	640
neuper@42279	641
neuper@42279	642
neuper@42279	643	section {Write Tests for Crucial Details}
neuper@42279	644	text{===================================}
neuper@42279	645	ML {*
neuper@42279	646
neuper@42279	647	*}
neuper@42279	648
neuper@42279	649	section {Integrate Program into Knowledge}
neuper@42279	650	ML {*
neuper@42290	651	@{theory Isac}
neuper@42279	652	*}
neuper@42279	653
neuper@42279	654	end
neuper@42279	655

author	Jan Rocnik <jan.rocnik@student.tugraz.at>
	Wed, 28 Sep 2011 10:18:20 +0200
branch	decompose-isar
changeset 42296	abd6d3c2d8bf
parent 42290	9e2a3695a25a
child 42297	d05076b48d6d
permissions	-rwxr-xr-x