(* Title:  Test_Z_Transform

   Author: Jan Rocnik

   (c) copyright due to lincense terms.

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*)

theory Inverse_Z_Transform imports PolyEq DiffApp Partial_Fractions begin

axiomatization where 

  rule1: "1 = \<delta>[n]" and

  rule2: "|| z || > 1 ==> z / (z - 1) = u [n]" and

  rule3: "|| z || < 1 ==> z / (z - 1) = -u [-n - 1]" and 

  rule4: "c * (z / (z - \<alpha>)) = c * \<alpha>^^^n * u [n]" and

  rule5: "|| z || < || \<alpha> || ==> z / (z - \<alpha>) = -(\<alpha>^^^n) * u [-n - 1]" and

  rule6: "|| z || > 1 ==> z/(z - 1)^^^2 = n * u [n]" (*and

  rule42: "(a * (z/(z-b)) + c * (z/(z-d))) = (a * b^^^n * u [n] + c * d^^^n * u [n])"*)

axiomatization where

  ruleZY: "(X z = a / b) = (X' z = a / (z * b))" and

  ruleYZ: "(a/b + c/d) = (a*(z/b) + c*(z/d))" 

subsection\<open>Define the Field Descriptions for the specification\<close>

consts

  filterExpression  :: "bool => una"

  stepResponse      :: "bool => una"

ML \<open>

val inverse_z = prep_rls'(

  Rule.Rls {id = "inverse_z", preconds = [], rew_ord = ("dummy_ord",Rule.dummy_ord), 

	  erls = Rule.Erls, srls = Rule.Erls, calc = [], errpatts = [],

	  rules = 

	   [

    Rule.Thm ("rule4", @{thm rule4})

	   ], 

	 scr = Rule.EmptyScr});

\<close>

text \<open>store the rule set for math engine\<close>

setup \<open>KEStore_Elems.add_rlss [("inverse_z", (Context.theory_name @{theory}, inverse_z))]\<close>

subsection\<open>Define the Specification\<close>

ML \<open>

val thy = @{theory};

\<close>

setup \<open>KEStore_Elems.add_pbts

  [(Specify.prep_pbt thy "pbl_SP" [] Celem.e_pblID (["SignalProcessing"], [], Rule.e_rls, NONE, [])),

    (Specify.prep_pbt thy "pbl_SP_Ztrans" [] Celem.e_pblID

      (["Z_Transform","SignalProcessing"], [], Rule.e_rls, NONE, [])),

    (Specify.prep_pbt thy "pbl_SP_Ztrans_inv" [] Celem.e_pblID

      (["Inverse", "Z_Transform", "SignalProcessing"],

        (*^ capital letter breaks coding standard

          because "inverse" = Const ("Rings.inverse_class.inverse", ..*)

        [("#Given" ,["filterExpression (X_eq::bool)"]),

          ("#Find"  ,["stepResponse (n_eq::bool)"])],

        Rule.append_rls "e_rls" Rule.e_rls [(*for preds in where_*)], NONE, 

        [["SignalProcessing","Z_Transform","Inverse"]])),

    (Specify.prep_pbt thy "pbl_SP_Ztrans_inv" [] Celem.e_pblID

      (["Inverse", "Z_Transform", "SignalProcessing"],

        [("#Given" ,["filterExpression X_eq"]),

          ("#Find"  ,["stepResponse n_eq"])],

        Rule.append_rls "e_rls" Rule.e_rls [(*for preds in where_*)], NONE, 

        [["SignalProcessing","Z_Transform","Inverse"]]))]\<close>

subsection \<open>Define Name and Signature for the Method\<close>

consts

  InverseZTransform :: "[bool, bool] => bool"

    ("((Script InverseZTransform (_ =))// (_))" 9)

subsection \<open>Setup Parent Nodes in Hierarchy of Method\<close>

ML \<open>val thy = @{theory}; (*latest version of thy required*)\<close>

setup \<open>KEStore_Elems.add_mets

    [Specify.prep_met thy "met_SP" [] Celem.e_metID

      (["SignalProcessing"], [],

        {rew_ord'="tless_true", rls'= Rule.e_rls, calc = [], srls = Rule.e_rls, prls = Rule.e_rls, crls = Rule.e_rls,

          errpats = [], nrls = Rule.e_rls}, "empty_script"),

    Specify.prep_met thy "met_SP_Ztrans" [] Celem.e_metID

      (["SignalProcessing", "Z_Transform"], [],

        {rew_ord'="tless_true", rls'= Rule.e_rls, calc = [], srls = Rule.e_rls, prls = Rule.e_rls, crls = Rule.e_rls,

          errpats = [], nrls = Rule.e_rls}, "empty_script")]

\<close>

setup \<open>KEStore_Elems.add_mets

    [Specify.prep_met thy "met_SP_Ztrans_inv" [] Celem.e_metID

      (["SignalProcessing", "Z_Transform", "Inverse"], 

        [("#Given" ,["filterExpression (X_eq::bool)"]),

          ("#Find"  ,["stepResponse (n_eq::bool)"])],

        {rew_ord'="tless_true", rls'= Rule.e_rls, calc = [], srls = Rule.e_rls, prls = Rule.e_rls, crls = Rule.e_rls,

          errpats = [], nrls = Rule.e_rls},

        "Script InverseZTransform (X_eq::bool) =" ^ (*(1/z) instead of z ^^^ -1*)

          " (let X = Take X_eq;" ^

          "      X' = Rewrite ruleZY False X;" ^ (*z * denominator*)

          "      X' = (Rewrite_Set norm_Rational False) X';" ^ (*simplify*)

          "      funterm = Take (rhs X');" ^ (*drop X' z = for equation solving*)

          "      denom = (Rewrite_Set partial_fraction False) funterm;" ^ (*get_denominator*)

          "      equ = (denom = (0::real));" ^

          "      fun_arg = Take (lhs X');" ^

          "      arg = (Rewrite_Set partial_fraction False) X';" ^ (*get_argument TODO*)

          "      (L_L::bool list) =                                    " ^

          "            (SubProblem (Test',                            " ^

          "                         [LINEAR,univariate,equation,test]," ^

          "                         [Test,solve_linear])              " ^

          "                        [BOOL equ, REAL z])              " ^

          "  in X)")]

\<close>

setup \<open>KEStore_Elems.add_mets

    [Specify.prep_met thy "met_SP_Ztrans_inv" [] Celem.e_metID

      (["SignalProcessing", "Z_Transform", "Inverse"], 

        [("#Given" ,["filterExpression X_eq"]),

          ("#Find"  ,["stepResponse n_eq"])],

        {rew_ord'="tless_true", rls'= Rule.e_rls, calc = [], srls = srls_partial_fraction, prls = Rule.e_rls,

          crls = Rule.e_rls, errpats = [], nrls = Rule.e_rls},

        "Script InverseZTransform (X_eq::bool) =                        "^

           (*(1/z) instead of z ^^^ -1*)

           "(let X = Take X_eq;                                            "^

           "      X' = Rewrite ruleZY False X;                             "^

           (*z * denominator*)

           "      (num_orig::real) = get_numerator (rhs X');               "^

           "      X' = (Rewrite_Set norm_Rational False) X';               "^

           (*simplify*)

           "      (X'_z::real) = lhs X';                                   "^

           "      (zzz::real) = argument_in X'_z;                          "^

           "      (funterm::real) = rhs X';                                "^

           (*drop X' z = for equation solving*)

           "      (denom::real) = get_denominator funterm;                 "^

           (*get_denominator*)

           "      (num::real) = get_numerator funterm;                     "^

           (*get_numerator*)

           "      (equ::bool) = (denom = (0::real));                       "^

           "      (L_L::bool list) = (SubProblem (PolyEq',                 "^

           "         [abcFormula,degree_2,polynomial,univariate,equation], "^

           "         [no_met])                                             "^

           "         [BOOL equ, REAL zzz]);                                "^

           "      (facs::real) = factors_from_solution L_L;                "^

           "      (eql::real) = Take (num_orig / facs);                    "^ 

           "      (eqr::real) = (Try (Rewrite_Set ansatz_rls False)) eql;  "^

           "      (eq::bool) = Take (eql = eqr);                           "^

           (*Maybe possible to use HOLogic.mk_eq ??*)

           "      eq = (Try (Rewrite_Set equival_trans False)) eq;         "^ 

           "      eq = drop_questionmarks eq;                              "^

           "      (z1::real) = (rhs (NTH 1 L_L));                          "^

           (* 

            * prepare equation for a - eq_a

            * therefor substitute z with solution 1 - z1

            *)

           "      (z2::real) = (rhs (NTH 2 L_L));                          "^

           "      (eq_a::bool) = Take eq;                                  "^

           "      eq_a = (Substitute [zzz=z1]) eq;                         "^

           "      eq_a = (Rewrite_Set norm_Rational False) eq_a;           "^

           "      (sol_a::bool list) =                                     "^

           "                 (SubProblem (Isac',                           "^

           "                              [univariate,equation],[no_met])  "^

           "                              [BOOL eq_a, REAL (A::real)]);    "^

           "      (a::real) = (rhs(NTH 1 sol_a));                          "^

           "      (eq_b::bool) = Take eq;                                  "^

           "      eq_b =  (Substitute [zzz=z2]) eq_b;                      "^

           "      eq_b = (Rewrite_Set norm_Rational False) eq_b;           "^

           "      (sol_b::bool list) =                                     "^

           "                 (SubProblem (Isac',                           "^

           "                              [univariate,equation],[no_met])  "^

           "                              [BOOL eq_b, REAL (B::real)]);    "^

           "      (b::real) = (rhs(NTH 1 sol_b));                          "^

           "      eqr = drop_questionmarks eqr;                            "^

           "      (pbz::real) = Take eqr;                                  "^

           "      pbz = ((Substitute [A=a, B=b]) pbz);                     "^

           "      pbz = Rewrite ruleYZ False pbz;                          "^

           "      pbz = drop_questionmarks pbz;                            "^

           "      (X_z::bool) = Take (X_z = pbz);                          "^

           "      (n_eq::bool) = (Rewrite_Set inverse_z False) X_z;        "^

           "      n_eq = drop_questionmarks n_eq                           "^

           "in n_eq)")]

\<close>

setup \<open>KEStore_Elems.add_mets

    [Specify.prep_met thy "met_SP_Ztrans_inv_sub" [] Celem.e_metID

      (["SignalProcessing", "Z_Transform", "Inverse_sub"], 

        [("#Given" ,["filterExpression X_eq"]),

          ("#Find"  ,["stepResponse n_eq"])],

        {rew_ord'="tless_true", rls'= Rule.e_rls, calc = [],

          srls = Rule.Rls {id="srls_partial_fraction", 

              preconds = [], rew_ord = ("termlessI",termlessI),

              erls = Rule.append_rls "erls_in_srls_partial_fraction" Rule.e_rls

                  [(*for asm in NTH_CONS ...*)

                    Rule.Calc ("Orderings.ord_class.less",eval_equ "#less_"),

                    (*2nd NTH_CONS pushes n+-1 into asms*)

                    Rule.Calc("Groups.plus_class.plus", eval_binop "#add_")], 

              srls = Rule.Erls, calc = [], errpatts = [],

              rules = [Rule.Thm ("NTH_CONS", @{thm NTH_CONS}),

                  Rule.Calc ("Groups.plus_class.plus", eval_binop "#add_"),

                  Rule.Thm ("NTH_NIL", @{thm NTH_NIL}),

                  Rule.Calc ("Tools.lhs", eval_lhs "eval_lhs_"),

                  Rule.Calc ("Tools.rhs", eval_rhs"eval_rhs_"),

                  Rule.Calc ("Atools.argument'_in", eval_argument_in "Atools.argument'_in"),

                  Rule.Calc ("Rational.get_denominator", eval_get_denominator "#get_denominator"),

                  Rule.Calc ("Rational.get_numerator", eval_get_numerator "#get_numerator"),

                  Rule.Calc ("Partial_Fractions.factors_from_solution",

                    eval_factors_from_solution "#factors_from_solution"),

                  Rule.Calc("Partial_Fractions.drop_questionmarks", eval_drop_questionmarks "#drop_?")],

              scr = Rule.EmptyScr},

          prls = Rule.e_rls, crls = Rule.e_rls, errpats = [], nrls = norm_Rational},

        (*([], Frm), Problem (Isac, [Inverse, Z_Transform, SignalProcessing])*)

        "Script InverseZTransform (X_eq::bool) =            "^

          (*([1], Frm), X z = 3 / (z - 1 / 4 + -1 / 8 * (1 / z))*)

          "(let X = Take X_eq;                                "^

          (*([1], Res), ?X' z = 3 / (z * (z - 1 / 4 + -1 / 8 * (1 / z)))*)

          "  X' = Rewrite ruleZY False X;                     "^

          (*            ?X' z*)

          "  (X'_z::real) = lhs X';                           "^

          (*            z *)

          "  (zzz::real) = argument_in X'_z;                  "^

          (*            3 / (z * (z - 1 / 4 + -1 / 8 * (1 / z)))*)

          "  (funterm::real) = rhs X';                        "^

          "  (pbz::real) = (SubProblem (Isac',                "^

          "    [partial_fraction,rational,simplification],    "^

          "    [simplification,of_rationals,to_partial_fraction]) "^

          (*([2], Res), 4 / (z - 1 / 2) + -4 / (z - -1 / 4)*)

          "    [REAL funterm, REAL zzz]);                     "^

          (*([3], Frm), ?X' z = 4 / (z - 1 / 2) + -4 / (z - -1 / 4)*)

          "  (pbz_eq::bool) = Take (X'_z = pbz);              "^

          (*([3], Res), ?X' z = 4 * (?z / (z - 1 / 2)) + -4 * (?z / (z - -1 / 4))*)

          "  pbz_eq = Rewrite ruleYZ False pbz_eq;            "^

          (*               4 * (z / (z - 1 / 2)) + -4 * (z / (z - -1 / 4))*)

          "  pbz_eq = drop_questionmarks pbz_eq;              "^

          (*([4], Frm), X_z = 4 * (z / (z - 1 / 2)) + -4 * (z / (z - -1 / 4))*)

          "  (X_zeq::bool) = Take (X_z = rhs pbz_eq);         "^

          (*([4], Res), X_z = 4 * (1 / 2) ^^^ ?n * ?u [?n] + -4 * (-1 / 4) ^^^ ?n * ?u [?n]*)

          "  n_eq = (Rewrite_Set inverse_z False) X_zeq;      "^

          (*            X_z = 4 * (1 / 2) ^^^ n * u [n] + -4 * (-1 / 4) ^^^ n * u [n]*)

          "  n_eq = drop_questionmarks n_eq                   "^

          (*([], Res), X_z = 4 * (1 / 2) ^^^ n * u [n] + -4 * (-1 / 4) ^^^ n * u [n]*)

          "in n_eq)")]

\<close>

end