/dports/science/lammps/lammps-stable_29Sep2021/doc/src/ |
H A D | pair_eff.rst | 106 E_{NN} = & \frac{1}{{4\pi \varepsilon _0 }}\sum\limits_{i < j} {\frac{{Z_i Z_j }}{{R_{ij} }}} \\ 107 …E_{Ne} = & - \frac{1}{{4\pi \varepsilon _0 }}\sum\limits_{i,j} {\frac{{Z_i }}{{R_{ij} }}Erf\left(… 112 fixed spins of the electrons, Z_i to the charges on the nuclei, R_ij
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H A D | pair_tersoff_zbl.rst | 148 * :math:`Z_i` 159 :math:`Z_i`, :math:`Z_j`, ZBLcut, ZBLexpscale parameters are used in the
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/dports/science/vipster/vipster-1.19.1b-14-g7168a1b/gui/qt/toolwidgets/lammpswidget_aux/ |
H A D | uff.lmp.cpp | 629 double Z_i = std::get<5>(UFF_Parameters.at(name1)); in UFF_PrepareParameters() local 631 …double k = 664.12 * Z_i * Z_k / std::pow(r_ik, 5) // beta reduced to 664.12 by eliminating the rad… in UFF_PrepareParameters()
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/dports/math/gretl/gretl-2021d/addons/HIP/ |
H A D | HIP_public.inp | 9 y_i = Z_i'\beta + \epsilon_i 10 Z_i = ENDOG_i EXOG_i (Y_i X_1i)
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/dports/devel/boost-python-libs/boost_1_72_0/libs/graph/doc/ |
H A D | transitive_closure.w | 287 $Z_i$ is a path in $G$ and the vertices in a chain have increasing 290 \bigcup_{i=1 \ldots k} (Z_i \cap S)$. Each intersection can be represented 291 by the first vertex in the path $Z_i$ that is also in $S$, since the 295 intersection of $S$ with $Z_i$.
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/dports/devel/boost-docs/boost_1_72_0/libs/graph/doc/ |
H A D | transitive_closure.w | 287 $Z_i$ is a path in $G$ and the vertices in a chain have increasing 290 \bigcup_{i=1 \ldots k} (Z_i \cap S)$. Each intersection can be represented 291 by the first vertex in the path $Z_i$ that is also in $S$, since the 295 intersection of $S$ with $Z_i$.
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/dports/databases/percona57-pam-for-mysql/boost_1_59_0/libs/graph/doc/ |
H A D | transitive_closure.w | 287 $Z_i$ is a path in $G$ and the vertices in a chain have increasing 290 \bigcup_{i=1 \ldots k} (Z_i \cap S)$. Each intersection can be represented 291 by the first vertex in the path $Z_i$ that is also in $S$, since the 295 intersection of $S$ with $Z_i$.
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/dports/databases/mysqlwsrep57-server/boost_1_59_0/libs/graph/doc/ |
H A D | transitive_closure.w | 287 $Z_i$ is a path in $G$ and the vertices in a chain have increasing 290 \bigcup_{i=1 \ldots k} (Z_i \cap S)$. Each intersection can be represented 291 by the first vertex in the path $Z_i$ that is also in $S$, since the 295 intersection of $S$ with $Z_i$.
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/dports/databases/percona57-server/boost_1_59_0/libs/graph/doc/ |
H A D | transitive_closure.w | 287 $Z_i$ is a path in $G$ and the vertices in a chain have increasing 290 \bigcup_{i=1 \ldots k} (Z_i \cap S)$. Each intersection can be represented 291 by the first vertex in the path $Z_i$ that is also in $S$, since the 295 intersection of $S$ with $Z_i$.
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/dports/databases/xtrabackup/boost_1_59_0/libs/graph/doc/ |
H A D | transitive_closure.w | 287 $Z_i$ is a path in $G$ and the vertices in a chain have increasing 290 \bigcup_{i=1 \ldots k} (Z_i \cap S)$. Each intersection can be represented 291 by the first vertex in the path $Z_i$ that is also in $S$, since the 295 intersection of $S$ with $Z_i$.
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/dports/databases/percona57-client/boost_1_59_0/libs/graph/doc/ |
H A D | transitive_closure.w | 287 $Z_i$ is a path in $G$ and the vertices in a chain have increasing 290 \bigcup_{i=1 \ldots k} (Z_i \cap S)$. Each intersection can be represented 291 by the first vertex in the path $Z_i$ that is also in $S$, since the 295 intersection of $S$ with $Z_i$.
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/dports/devel/boost-libs/boost_1_72_0/libs/graph/doc/ |
H A D | transitive_closure.w | 287 $Z_i$ is a path in $G$ and the vertices in a chain have increasing 290 \bigcup_{i=1 \ldots k} (Z_i \cap S)$. Each intersection can be represented 291 by the first vertex in the path $Z_i$ that is also in $S$, since the 295 intersection of $S$ with $Z_i$.
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/dports/devel/hyperscan/boost_1_75_0/libs/graph/doc/ |
H A D | transitive_closure.w | 287 $Z_i$ is a path in $G$ and the vertices in a chain have increasing 290 \bigcup_{i=1 \ldots k} (Z_i \cap S)$. Each intersection can be represented 291 by the first vertex in the path $Z_i$ that is also in $S$, since the 295 intersection of $S$ with $Z_i$.
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/dports/science/openkim-models/openkim-models-2021-01-28/model-drivers/EDIP__MD_506186535567_002/ |
H A D | README | 43 … the asymmetry the coordination introduces into the 2-body energy (V2(R_ij,Z_i) != V2(R_ji,Z_j)). …
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/dports/math/pspp/pspp-1.4.1/doc/ |
H A D | regression.texi | 32 @math{Y_i = b_0 + b_1 X_{1i} + ... + b_k X_{ki} + Z_i}
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/dports/math/R-cran-lme4/lme4/inst/doc/ |
H A D | lmer.Rnw | 665 Z_i$, which we refer to as the \emph{term-wise model matrix} for the 672 Creating the matrix $\bm Z_i$ from $\bm X_i$ and $\bm J_i$ is a 674 describe. Consider $\bm Z_i$ as being further decomposed into 679 $\bm Z_i$, for the $i$th term as a transposed Khatri-Rao product, 682 \bm Z_i = (\bm J_i\trans * \bm X_i\trans)\trans = 719 In particular, for a simple, scalar term, $\bm Z_i$ is exactly $\bm 724 Because each $\bm Z_i$ is generated from indicator columns, its 725 cross-product, $\bm Z_i\trans\bm Z_i$ is block-diagonal consisting of 728 cross-product matrix $Z_i\trans Z_i$ as $\sum_{j=1}^n \bm J_{ij} \bm 735 $Z_i\trans Z_i$.} Note that this means that when $k=1$ (i.e., there [all …]
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/dports/math/R-cran-lme4/lme4/vignettes/ |
H A D | lmer.Rnw | 665 Z_i$, which we refer to as the \emph{term-wise model matrix} for the 672 Creating the matrix $\bm Z_i$ from $\bm X_i$ and $\bm J_i$ is a 674 describe. Consider $\bm Z_i$ as being further decomposed into 679 $\bm Z_i$, for the $i$th term as a transposed Khatri-Rao product, 682 \bm Z_i = (\bm J_i\trans * \bm X_i\trans)\trans = 719 In particular, for a simple, scalar term, $\bm Z_i$ is exactly $\bm 724 Because each $\bm Z_i$ is generated from indicator columns, its 725 cross-product, $\bm Z_i\trans\bm Z_i$ is block-diagonal consisting of 728 cross-product matrix $Z_i\trans Z_i$ as $\sum_{j=1}^n \bm J_{ij} \bm 735 $Z_i\trans Z_i$.} Note that this means that when $k=1$ (i.e., there [all …]
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/dports/science/openkim-models/openkim-models-2021-01-28/model-drivers/Tersoff_LAMMPS__MD_077075034781_004/ |
H A D | model_driver_Tersoff.cpp | 622 REGZBL(Z_i, Zi, (unitless)); in reg_params()
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/dports/math/gap/gap-4.11.0/pkg/qpa-version-1.30/lib/ |
H A D | complex.gi | 840 ## ... --> C_{i+1} --> Z_i --> 0 --> 0 --> ... 842 ## where Z_i is the i-cycle of C. 871 ## ... --> 0 --> C_i/Z_i --> C_{i-1} --> 0 --> ... 873 ## where Z_i is the i-cycle of C.
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/dports/math/gap/gap-4.11.0/pkg/sonata-2.9.1/doc/ref/ |
H A D | fpf.tex | 452 $\{ (P, Q, A_i,B_i, Z_i) | i$ in $indexlist \}$ over GF(<p>) as well as the 456 $\{ (P, Q, A_i, Z_i) | i$ in $indexlist \}$ over GF(<p>) and $indexlist$. 460 $a \mapsto A_i, b \mapsto B_i, z \mapsto Z_i$
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/dports/science/gromacs/gromacs-2021.4/docs/reference-manual/functions/ |
H A D | restraints.rst | 47 …_i)^2 ~{\hat{\bf x}} + k_{pr}^y (y_i-Y_i)^2 ~{\hat{\bf y}} + k_{pr}^z (z_i-Z_i)^2 ~{\hat{\bf z}}\r… 55 F_i^z &=& -k_{pr}^z~(z_i - Z_i) 134 d_g(\mathbf{r}_i;\mathbf{R}_i) = |z_i-Z_i|.
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/dports/science/chrono/chrono-7.0.1/doxygen/documentation/tutorials/chrono/ |
H A D | demo_powertrain.md | 142 the transmission ratio \f$ t_0 \f$ that we get. It is simply \f$ t_0=-Z_a/Z_c \f$, with \f$ Z_i \f$…
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/dports/science/py-cirq-ionq/Cirq-0.13.1/docs/tutorials/ |
H A D | qaoa.ipynb | 291 " H_C = \\frac{1}{2} \\sum_{\\langle i, j\\rangle} w_{ij} (1 - Z_i Z_j )\n", 296 …Z_i Z_j \\rangle = 1$ and so $\\frac{1}{2} w_{ij} \\langle 1 - Z_i Z_j \\rangle = 0$. In the Max-C…
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/dports/science/py-cirq-pasqal/Cirq-0.13.1/docs/tutorials/ |
H A D | qaoa.ipynb | 291 " H_C = \\frac{1}{2} \\sum_{\\langle i, j\\rangle} w_{ij} (1 - Z_i Z_j )\n", 296 …Z_i Z_j \\rangle = 1$ and so $\\frac{1}{2} w_{ij} \\langle 1 - Z_i Z_j \\rangle = 0$. In the Max-C…
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/dports/science/py-cirq-core/Cirq-0.13.1/docs/tutorials/ |
H A D | qaoa.ipynb | 291 " H_C = \\frac{1}{2} \\sum_{\\langle i, j\\rangle} w_{ij} (1 - Z_i Z_j )\n", 296 …Z_i Z_j \\rangle = 1$ and so $\\frac{1}{2} w_{ij} \\langle 1 - Z_i Z_j \\rangle = 0$. In the Max-C…
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