1 | /* -*- Mode: Maxima -*- */
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2 |
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3 | /*
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4 | **
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5 | ** Copyright (C) 1999, 2002, 2009 Marek Rychlik <rychlik@u.arizona.edu>
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6 | **
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7 | ** This program is free software; you can redistribute it and/or modify
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8 | ** it under the terms of the GNU General Public License as published by
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9 | ** the Free Software Foundation; either version 2 of the License, or
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10 | ** (at your option) any later version.
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11 | **
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12 | ** This program is distributed in the hope that it will be useful,
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13 | ** but WITHOUT ANY WARRANTY; without even the implied warranty of
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14 | ** MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
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15 | ** GNU General Public License for more details.
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16 | **
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17 | ** You should have received a copy of the GNU General Public License
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18 | ** along with this program; if not, write to the Free Software
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19 | ** Foundation, Inc., 59 Temple Place - Suite 330, Boston, MA 02111-1307, USA.
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20 | **
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21 | */
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22 | showtime:true;
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23 |
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24 | /* POLY_MONOMIAL_ORDER switch represents the monomial order that will globally be in effect
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25 | for the succeeding operations. */
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26 |
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27 | poly_monomial_order:'lex;
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28 |
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29 | /* POLY_EXPAND parses polynomials to internal form and back. It can be used to test
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30 | whether an expression correctly parses to the internal representation.
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31 | The following examples illustrate that indexed and transcendental function variables
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32 | are allowed. */
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33 |
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34 | poly_expand(x,[x,y]);
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35 | poly_expand(x+y,[x,y]);
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36 | poly_expand(x-y,[x,y]);
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37 | poly_expand((x-y)*(x+y),[x,y]);
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38 | poly_expand((x+y)^2,[x,y]);
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39 | poly_expand((x+y)^5,[x,y]);
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40 | poly_expand(x/y-1,[x]);
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41 | poly_expand(x^2/sqrt(y)-x*exp(y)-1,[x]);
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42 | poly_expand(sin(x)-sin(x)^2-1,[sin(x)]);
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43 | poly_expand((x[2]/sin(y[3])-1)^5,[x[2]]),poly_return_term_list:true;
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44 |
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45 | /* POLY_ADD, POLY_SUBTRACT, POLY_MULTIPLY and POLY_EXPT are the arithmetical operations on polynomials.
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46 | These are performed using the internal representation, but the results are converted back to the
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47 | Maxima general form */
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48 |
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49 | poly_add(x^2*y+z,x-z,[x,y,z]);
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50 | poly_subtract(x^2*y+z,x-z,[x,y,z]);
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51 | poly_multiply(x^2*y+z,x-z,[x,y,z]) - (x^2*y+z)*(x-z), expand;
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52 | poly_expt(x-y, 3, [x,y]) - (x-y)^3, expand;
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53 |
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54 | /* POLY_CONTENT extracts the GCD of its coefficients */
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55 | poly_content(21*x+35*y,[x,y]);
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56 |
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57 | /* POLY_PRIMITIVE_PART divides a polynomial by the GCD of its coefficients */
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58 | poly_primitive_part(21*x+35*y,[x,y]);
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59 |
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60 | /* POLY_S_POLYNOMIAL computest the syzygy polynomial (S-polynomial) of two polynomials */
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61 | poly_s_polynomial(x+y,x-y,[x,y]);
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62 |
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63 |
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64 | /* POLY_NORMAL_FORM finds the normal form of a polynomial with respect to a set of polynomials. */
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65 | poly_normal_form(x^2+y^2,[x-y,x+y],[x,y]);
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66 | poly_pseudo_divide(2*x^2+3*y^2,[7*x-y^2,11*x+y],[x,y]);
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67 | poly_exact_divide((x+y)^2,x+y,[x,y]);
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68 |
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69 | /* POLY_BUCHBERGER performs the Buchberger algorithm on a list of polynomials and returns
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70 | the resulting Grobner basis */
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71 | poly_buchberger([x^2-y*x,x^2+y+x*y^2],[x,y]);
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72 |
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73 | /* POLY_REDUCTION reduces a set of polynomials, so that
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74 | each polynomial is fully reduced with respect to the other polynomials */
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75 |
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76 | poly_reduction([x^2-x*y,x*y^2+y+x^2,x*y^2+x*y+y,x*y-y^2,y^3+y^2+y],[x,y]);
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77 |
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78 | /* POLY_MINIMIZATION selects a subset of a set of polynomials, so that no leading monomial is divisible by
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79 | another leading monomial */
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80 |
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81 | poly_minimization([x^2-x*y,x*y^2+y+x^2,x*y^2+x*y+y,x*y-y^2,y^3+y^2+y],[x,y]);
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82 |
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83 | /* POLY_REDUCED_GROBNER returns a reduced Grobner basis */
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84 | poly_reduced_grobner([x^2-y*x,x^2+y+x*y^2],[x,y]);
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85 |
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86 | /* POLY_NORMALIZE divides a polynomial by its leading coefficient */
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87 | poly_normalize(2*x+y,[x,y]);
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88 |
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89 | /* POLY_NORMALIZE_LIST applies POLY_NORMALIZE to each polynomial in the list */
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90 |
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91 | poly_normalize_list([2*x+y,3*x^2+7],[x,y]);
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92 |
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93 | /* POLY_DEPENDS_P tests whether a polynomial depends on a variable */
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94 |
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95 | poly_depends_p(x^2+y,x,[x,y,z]);
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96 | poly_depends_p(x^2+y,z,[x,y,z]);
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97 |
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98 |
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99 | /* POLY_ELIMINATION_IDEAL returns the grobner basis of the K-th elimination ideal of an
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100 | ideal specified as a list of generating polynomials (not necessarily Grobner basis */
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101 |
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102 | poly_elimination_ideal([x+y,x-y],0,[x,y]);
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103 | poly_elimination_ideal([x+y,x-y],1,[x,y]);
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104 | poly_elimination_ideal([x+y,x-y],2,[x,y]);
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105 |
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106 | /* POLY_IDEAL_INTERSECTION returns the intersection of two ideals */
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107 | poly_ideal_intersection([x^2+y,x^2-y],[x,y^2],[x,y]);
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108 |
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109 | /* POLY_LCM and POLY_GCD are the Grobner versions of LCM and GCD */
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110 |
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111 | poly_lcm(x*y^2-x,x^2*y+x,[x,y]);
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112 | poly_gcd(x*y^2-x,x^2*y+x,[x,y]);
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113 |
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114 | /* POLY_GROBNER_MEMBER tests whether a polynomial belongs to an ideal generated by a list of polynomials,
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115 | which is assumed to be a Grobner basis. Equivalent to NORMAL_FORM being 0. */
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116 |
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117 | poly_grobner_member(x+y,[x,y],[x,y]);
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118 |
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119 | /* POLY_GROBNER_EQUAL tests whether two Grobner bases generate the same ideal.
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120 | This is equivalent to checking that every polynomial of the first basis reduces to 0
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121 | modulo the second basis and vice versa. Note that in the example below the
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122 | first list is not a Grobner basis, and thus the result is FALSE. */
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123 |
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124 | poly_grobner_equal([x+y,x-y],[x,y],[x,y]);
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125 |
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126 | /* POLY_GROBNER_SUBSETP tests whether an ideal generated by the first list of polynomials
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127 | is contained in the ideal generated by the second list. For this test to always succeed,
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128 | the second list must be a Grobner basis */
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129 |
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130 | poly_grobner_subsetp([x+y,x-y],[x,y],[x,y]);
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131 |
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132 | /* POLY_POLYSATURATION_EXTENSION implements the famous Rabinowitz trick. */
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133 | poly_polysaturation_extension([x,y],[x^2,y^3],[x,y],[u,v]);
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134 |
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135 | poly_saturation_extension([x,y],[x^2,y^3],[x,y],[u,v]);
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136 |
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137 | /* POLY_IDEAL_POLYSATURATION1 for a given ideal I and polynomials f, g, ..., finds
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138 | the colon ideal I : f^inf : g^inf : ... */
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139 | poly_ideal_polysaturation1([x,y],[x^2,y^3],[x,y]);
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140 |
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141 | /* POLY_IDEAL_SATURATION for given ideals I and J computes the ideal I : J^inf. */
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142 | poly_ideal_saturation([x,y],[x^2,y^3],[x,y]);
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143 |
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144 | /* POLY_IDEAL_POLYSATURATION for a given ideal I and a sequence of ideals J1, J2, J3, ...,
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145 | finds the ideal I : J1^inf : J2^inf : J3^inf : ... */
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146 | poly_ideal_polysaturation([x,y],[[x^2],[y^3]],[x,y]);
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147 | poly_ideal_polysaturation([x^4-y^4], [[x-y],[x^2+y^2, x+y]],[x,y]);
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148 |
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149 | /* POLY_COLON_IDEAL finds the reduced Grobner basis of the colon ideal I:J, i.e. the set of polynomials H
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150 | such that for every polynomial G in I there is a polynomial F in J for which H*F=G;
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151 | in other words, I:J = {h: h*J is contained in I} */
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152 |
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153 | poly_colon_ideal([x^2*y],[y],[x,y]);
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154 |
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155 | /* POLY_BUCHBERGER_CRITERION verifies whether a given set of polynomials is a Grobner basis with respect
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156 | to the current term order */
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157 | poly_buchberger_criterion([x,y],[x,y]);
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158 | poly_buchberger_criterion([x-y,x+y],[x,y]);
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159 |
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160 | /* Grobner basis associated with Enneper minimal surface */
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161 | poly_grobner([x-3*u-3*u*v^2+u^3,y-3*v-3*u^2*v+v^3,z-3*u^2+3*v^2],[u,v,x,y,z]);
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162 | poly_reduced_grobner([x-3*u-3*u*v^2+u^3,y-3*v-3*u^2*v+v^3,z-3*u^2+3*v^2],[u,v,x,y,z]);
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163 |
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164 | /* Cyclic roots of degree 5 */
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165 | poly_reduced_grobner([x+y+z+u+v,x*y+y*z+z*u+u*v+v*x,x*y*z+y*z*u+z*u*v+u*v*x+v*x*y,x*y*z*u+y*z*u*v+z*u*v*x+u*v*x*y+v*x*y*z,x*y*z*u*v-1],[u,v,x,y,z]);
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166 |
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167 | /* The next example demonstrates the use of the switch
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168 | POLY_RETURN_TERM_LIST, which, if set to TRUE, makes the results to
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169 | appear as lists of terms listed in the current monomial order rather
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170 | than a general form expression */
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171 |
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172 | block([orders:[lex,grlex,grevlex,invlex]],
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173 | for i:1 thru length(orders) do (
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174 | print(ev([orders[i], poly_expand((x^2+x+y)^3,[x,y])], poly_monomial_order=orders[i]))
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175 | )
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176 | ), poly_return_term_list=true;
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177 |
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178 | /* Grobner bases can be computed over coefficient ring of maxima general expressions */
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179 | poly_grobner([x*y-1,x+y],[x]);
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180 |
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181 | /* A tough example learned from Cox */
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182 | poly_grobner([x^5+y^4+z^3-1,x^3+y^3+z^2-1], [x,y,z]);
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183 |
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184 | /* An even tougher example of Cox */
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185 | poly_grobner([x^5+y^4+z^3-1,x^3+y^3+z^2-1], [x,y,z]);
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186 |
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187 | /* We can also perform Grobner basis calculations modulo prime */
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188 | poly_grobner([x^5+y^4+z^3-1,x^3+y^3+z^2-1], [x,y,z]), modulus=3;
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189 |
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190 | /* We can also explicitly ask for the Grobner basis to be calculated using only
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191 | integer coefficients. An error will result if this assertion is not satisfied. */
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192 | poly_grobner([x^5+y^4+z^3-1,x^3+y^3+z^2-1], [x,y,z]), poly_coefficient_ring='ring_of_integers;
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193 |
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194 | /* The following several tests demonstrate the use of jet variables useful in processing differential equations */
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195 |
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196 |
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197 | /* Clear some variables */
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198 | kill(ode,t,x,y,u,v,r);
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199 |
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200 | /* Set up dependencies */
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201 | depends([x,y,u,v,r],t);
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202 |
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203 | /* These are equations representing mathematical pendulum */
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204 | ode:[x^2+y^2-c,'diff(x,t)-u,'diff(y,t)-v,'diff(u,t)+r*x,'diff(v,t)+r*y+1];
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205 |
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206 | jet_vars(k):=apply(append,reverse(makelist(['diff(x,t,j),'diff(y,t,j),'diff(u,t,j),'diff(v,t,j),'diff(r,t,j)],j,0,k+1)));
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207 |
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208 | /* Define k-fold prolongation */
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209 | prolongate(k):=apply(append,makelist(diff(ode,t,j),j,0,k));
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210 |
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211 | /* Define Grobner basis of k-fold prolongation */
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212 | gb(k):=poly_reduced_grobner(prolongate(k),jet_vars(k));
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213 |
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214 | /* Define the l-th projection of the k-th prolongation */
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215 | projection(l, k):=poly_elimination_ideal(prolongate(k),5*l,jet_vars(k));
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216 |
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217 | /* Compute some projections */
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218 | projection(0, 0);
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219 | projection(1, 1);
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