代码搜索:evaluate

找到约 3,619 项符合「evaluate」的源代码

代码结果 3,619
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m gkifit.m

function y=gkifit(d,s,b,m,bands); %function y=gkifit(d,s,b,m,bands); % % Evaluate the fit to the GKI at bands % % For more info, read README % % Michael Small % ensmall@polyu.edu.hk % 28/2/02 h2=ban
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www.eeworm.com/read/254517/7072428

m chebpoly.m

% CHEBPOLY Evaluate Chebyshev polynomial % % [Y]=CHEBPOLY(N, X) Evaluates the Nth Chebyshev polynomial at X function Y = chebpoly(N,X) X = X(:).'; T(1,:) = X; T(2,:) =
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www.eeworm.com/read/165343/7143970

mag erase.mag

// test the erasure decoder F := FiniteField(16); R := PolynomialRing(F); Gamma := (1-a^6*x)*(1-a^7*x); t := 3; f := 2; j1 := 7; j2 := 6; Y1 := a^j1; Y2 := a^j2; rt := a^5*x^11 + a^6*x^9 + a^
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www.eeworm.com/read/458493/7295669

m fx3n.m

function [f,dfdx] = fx3n(x) % fx3n Evaluate f(x) = x - x^(1/3) - 2 and dfdx for Newton algorithm f = x - x.^(1/3) - 2; dfdx = 1 - (1/3)*x.^(-2/3);
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www.eeworm.com/read/458493/7295754

m rhsdecay.m

function dydt = rhsDecay(t,y,flag,alpha) % rhsDecay Evaluate rhs of dy/dt = -alpha*y with a variable alpha. % "flag" parameter is required for compatability with ode45 dydt = -alpha*y;
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www.eeworm.com/read/458493/7295807

m expmx2.m

function y = expmx2(x) % expmx2 Evaluate exp(-x^2), where x is a scalar or vector y = exp(-x.^2);
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www.eeworm.com/read/458488/7296094

m fx3n.m

function [f,dfdx] = fx3n(x) % fx3n Evaluate f(x) = x - x^(1/3) - 2 and dfdx for Newton algorithm f = x - x.^(1/3) - 2; dfdx = 1 - (1/3)*x.^(-2/3);
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www.eeworm.com/read/458488/7296130

m rhsdecay.m

function dydt = rhsDecay(t,y,flag,alpha) % rhsDecay Evaluate rhs of dy/dt = -alpha*y with a variable alpha. % "flag" parameter is required for compatability with ode45 dydt = -alpha*y;
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www.eeworm.com/read/458488/7296183

m expmx2.m

function y = expmx2(x) % expmx2 Evaluate exp(-x^2), where x is a scalar or vector y = exp(-x.^2);
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www.eeworm.com/read/454211/7396371

m rosenbrockeval.m

function [val] = rosenbrockEval(sol) [m,n] = size(sol); f = zeros(m,n-1); for i = 1:n-1 f(:,i) = 100.*(sol(:,i+1)-sol(:,i).^2).^2+(sol(:,i)-1).^2; %calculation of Rosenbrock function end;
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