| /dports/math/p5-Math-GSL/Math-GSL-0.43/pm/Math/GSL/ |
| H A D | Linalg.pm.2.5 | 744 … The matrix Q is related to these components by, Q = Q_k ... Q_2 Q_1 where Q_i = I - \tau_i v_i v_…
|
| H A D | Linalg.pm.2.6 | 780 … The matrix Q is related to these components by, Q = Q_k ... Q_2 Q_1 where Q_i = I - \tau_i v_i v_…
|
| H A D | Linalg.pm.1.16 | 702 … The matrix Q is related to these components by, Q = Q_k ... Q_2 Q_1 where Q_i = I - \tau_i v_i v_…
|
| H A D | Linalg.pm.2.2.1 | 741 … The matrix Q is related to these components by, Q = Q_k ... Q_2 Q_1 where Q_i = I - \tau_i v_i v_…
|
| H A D | Linalg.pm.2.0 | 705 … The matrix Q is related to these components by, Q = Q_k ... Q_2 Q_1 where Q_i = I - \tau_i v_i v_…
|
| H A D | Linalg.pm.2.1 | 705 … The matrix Q is related to these components by, Q = Q_k ... Q_2 Q_1 where Q_i = I - \tau_i v_i v_…
|
| H A D | Linalg.pm.1.15 | 701 … The matrix Q is related to these components by, Q = Q_k ... Q_2 Q_1 where Q_i = I - \tau_i v_i v_…
|
| H A D | Linalg.pm.2.2 | 740 … The matrix Q is related to these components by, Q = Q_k ... Q_2 Q_1 where Q_i = I - \tau_i v_i v_…
|
| H A D | Linalg.pm.2.3 | 741 … The matrix Q is related to these components by, Q = Q_k ... Q_2 Q_1 where Q_i = I - \tau_i v_i v_…
|
| H A D | Linalg.pm.2.7 | 813 … The matrix Q is related to these components by, Q = Q_k ... Q_2 Q_1 where Q_i = I - \tau_i v_i v_…
|
| /dports/science/tfel/tfel-3.4.0/docs/presentations/mfront-formation/ |
| H A D | mfront-formation.tex.in | 1205 $ {\sigma_v}_i = a_i \left( e^{Q_i/T} \right)^{1/n_i} \left( p^{-} + \Delta p \right)^{m_i} \left(…
|
| /dports/science/tfel-edf/tfel-3.2.1/docs/presentations/mfront-formation/ |
| H A D | mfront-formation.tex.in | 1205 $ {\sigma_v}_i = a_i \left( e^{Q_i/T} \right)^{1/n_i} \left( p^{-} + \Delta p \right)^{m_i} \left(…
|
| /dports/misc/openmvg/openMVG-2.0/src/third_party/ceres-solver/docs/source/ |
| H A D | nnls_solving.rst | 1397 .. math:: \frac{Q_i - Q_{i-1}}{Q_i} < \frac{\eta}{i}
|
| /dports/math/ceres-solver/ceres-solver-2.0.0/docs/source/ |
| H A D | nnls_solving.rst | 1482 .. math:: \frac{Q_i - Q_{i-1}}{Q_i} < \frac{\eta}{i}
|
| /dports/graphics/lazpaint/lazpaint-7.1.6/resources/ |
| H A D | fillimages.lrs | 155 +#4'_'#161#25#246#7#232'!;j'#29'J'#178#245'Q_i'#134#174#139#14#24#234#17'`'
|
| /dports/math/gsl/gsl-2.7/doc/ |
| H A D | linalg.rst | 757 where :math:`Q_i = I - \tau_i v_i v_i^T` and :math:`v_i` is the
901 where :math:`Q_i = I - \tau_i v_i v_i^T` and :math:`v_i` is the
|
| H A D | gsl-ref.info | 11986 Q_k ... Q_2 Q_1 where Q_i = I - \tau_i v_i v_i^T and v_i is the
12143 is related to these components by, Q = Q_k ... Q_2 Q_1 where Q_i =
|
| /dports/biology/freebayes/freebayes-1.3.5/paper/ |
| H A D | main.tex | 584 … haplotype alleles is given as $\min ( q_l \, \forall \, b'_i \in H_i , \, Q_i)$, or the minimum o…
|
| /dports/multimedia/librav1e/rav1e-0.5.1/doc/ |
| H A D | quantizer-weight-analysis.ipynb | 11 "\\bar Q = \\sqrt{\\frac{\\sum_i N_i \\sigma_i^2}{\\sum_i \\frac{N_i \\sigma_i^2}{Q_i^2}}},\n",
15 …"{\\bar Q}^2 = \\frac1{\\frac{\\sum_i \\frac{N_i \\sigma_i^2}{Q_i^2}}{\\sum_i N_i \\sigma_i^2}}\n",
16 " = \\frac1{\\sum_i \\frac{\\frac{N_i \\sigma_i^2}{Q_i^2}}{\\sum_j N_j \\sigma_j^2}}\n",
17 …" = \\frac1{\\sum_i \\left(\\frac{N_i \\sigma_i^2}{\\sum_j N_j \\sigma_j^2} \\frac1{Q_i^2}\\right)…
523 "\\ln Q_i = \\ln \\bar Q \\cdot \\text{Q_MODEL_MUL}_i + \\text{Q_MODEL_ADD}_i.\n",
621 "\\log_2 Q_i = \\log_2 Q_{\\text{Y},\\text{AC}} \\cdot C + D,\n",
|
| /dports/multimedia/rav1e/rav1e-0.5.1/doc/ |
| H A D | quantizer-weight-analysis.ipynb | 11 "\\bar Q = \\sqrt{\\frac{\\sum_i N_i \\sigma_i^2}{\\sum_i \\frac{N_i \\sigma_i^2}{Q_i^2}}},\n",
15 …"{\\bar Q}^2 = \\frac1{\\frac{\\sum_i \\frac{N_i \\sigma_i^2}{Q_i^2}}{\\sum_i N_i \\sigma_i^2}}\n",
16 " = \\frac1{\\sum_i \\frac{\\frac{N_i \\sigma_i^2}{Q_i^2}}{\\sum_j N_j \\sigma_j^2}}\n",
17 …" = \\frac1{\\sum_i \\left(\\frac{N_i \\sigma_i^2}{\\sum_j N_j \\sigma_j^2} \\frac1{Q_i^2}\\right)…
523 "\\ln Q_i = \\ln \\bar Q \\cdot \\text{Q_MODEL_MUL}_i + \\text{Q_MODEL_ADD}_i.\n",
621 "\\log_2 Q_i = \\log_2 Q_{\\text{Y},\\text{AC}} \\cdot C + D,\n",
|
| /dports/math/gap/gap-4.11.0/lib/ |
| H A D | ctbl.gi | 2783 ## splits into distinct prime ideals $Q_i$ (i.e., with exponent $1$ each)
2787 ## $Q_i$ as the ideal spanned by $\alpha^k$,
|
| /dports/science/dalton/dalton-66052b3af5ea7225e31178bf9a8b031913c72190/DALTON/test/trueresult/ |
| H A D | cc_rsp_lanczos_alpha.ref | 3491 norm of Q_i+1 is 0.51572710186003601
|
| /dports/math/giacxcas/giac-1.6.0/doc/fr/ |
| H A D | algo.tex | 11247 remplacer les $Q_i$ par le reste euclidien de $Q_i$ par $P_i$ sans
|
| /dports/security/hashcat-legacy/hashcat-legacy-2.00/salts/ |
| H A D | brute-vbulletin.salt | 448284 Q_i
|
| /dports/databases/py-mysql-connector-python/mysql-connector-python-8.0.27/tests/data/ |
| H A D | random_big_bin.csv | 40798 ��I����7��_K�k��w�b"5$��~��}��{���1�h��[5��* �qa��>}�xׁeܞ �����A���(5���`5Q_i��P5?���A������g� ���…
|