' BV_GARCH.PRG (3/30/2004)
' example program for EViews LogL object
'
' restricted version of
' bi-variate BEKK of Engle and Kroner (1995):
'
'  y = mu + res
'  res ~ N(0,H)
'
'  H = omega*omega' + beta H(-1) beta' + alpha res(-1) res(-1)' alpha'
'
' where
'
'    y = 2 x 1
'    mu = 2 x 1
'      H = 2 x 2 (symmetric)
'          H(1,1) = variance of y1  (saved as var_y1)
'          H(1,2) = cov of y1 and y2 (saved as var_y2)
'          H(2,2) = variance of y2  (saved as cov_y1y2)
'  omega = 2 x 2 low triangular
'  beta = 2 x 2 diagonal
'  alpha = 2 x 2 diagonal
'
'change path to program path
%path = @runpath + "../data/"
cd %path
' load workfile
load cmw.wf1
' dependent variables of both series must be continues桥梁工程试题
smpl @all
series y1 =100*dlog(crb)
series y2 = 100*dlog(hushen300)
' set sample
' first observation of s1 need to be one or two periods after
' the first observation of s0
sample s0 1/5/2007 4/1/2011
sample s1 1/6/2007 4/1/2011
' initialization of parameters and starting values
' change below only to change the specification of model
smpl s0
'get starting values from univariate GARCH
equation eq1.arch(m=100,c=1e-5) y1 c
equation eq2.arch(m=100,c=1e-5) y2 c
yanyan的美食视频烘焙食谱
' declare coef vectors to use in bi-variate GARCH model
' see above for details
月子牙刷coef(2) mu
中国石拱桥课件
mu(1) = eq1.c(1)
mu(2)= eq2.c(1)
coef(3) omega
omega(1)=(eq1.c(2))^.5
omega(2)=0
omega(3)=eq2.c(2)^.5
coef(2) alpha
alpha(1) = (eq1.c(3))^.5
alpha(2) = (eq2.c(3))^.5
coef(2) beta
beta(1)= (eq1.c(4))^.5
beta(2)= (eq2.c(4))^.5
' constant adjustment for log likelihood
!mlog2pi = 2*log(2*@acos(-1))
' use var-cov of sample in "s1" as starting value of variance-covariance matrix
series cov_y1y2 = @cov(y1-mu(1), y2-mu(2))
小学六年级下册语文series var_y1 = @var(y1)
series var_y2 = @var(y2)
series sqres1 = (y1-mu(1))^2
series sqres2 = (y2-mu(2))^2
series res1res2 = (y1-mu(1))*(y2-mu(2))
' ...........................................................
' LOG LIKELIHOOD
' set up the likelihood
' 1) open a new blank likelihood object (L.O.) name bvgarch
' 2) specify the log likelihood model by append
' ...........................................................
logl bvgarch
bvgarch.append @logl logl
bvgarch.append sqres1 = (y1-mu(1))^22017广州一模
bvgarch.append sqres2 = (y2-mu(2))^2
bvgarch.append res1res2 = (y1-mu(1))*(y2-mu(2))
' calculate the variance and covariance series
bvgarch.append var_y1  =  omega(1)^2 + beta(1)^2*var_y1(-1) + alpha(1)^2*sqres1(-1)
bvgarch.append var_y2  = omega(3)^2+omega(2)^2 + beta(2)^2*var_y2(-1) + alpha(2)^2*sqres2(-1)
bvgarch.append cov_y1y2 = omega(1)*omega(2) + beta(2)*beta(1)*cov_y1y2(-1) + alpha(2)*alpha(1)*res1res2(-1)
' determinant of the variance-covariance matrix
bvgarch.append deth = var_y1*var_y2 - cov_y1y2^2
' inverse elements of the variance-covariance matrix
bvgarch.append invh1 = var_y2/deth
bvgarch.append invh3 = var_y1/deth
bvgarch.append invh2 = -cov_y1y2/deth
' log-likelihood series
bvgarch.append logl =-0.5*(!mlog2pi + (invh1*sqres1+2*invh2*res1res2+invh3*sqres2) + log(deth))
' remove some of the intermediary series
' bvgarch.append @temp invh1 invh2 invh3 sqres1 sqres2 res1res2 deth
' estimate the model
smpl s1
bvgarch.ml(showopts, m=100, c=1e-5)
  ' change below to display different output
show bvgarch.output
graph varcov.line var_y1 var_y2 cov_y1y2
show varcov
' LR statistic for univariate versus bivariate model
'scalar lr = -2*( eq1.@logl + eq2.@logl - bvgarch.@logl )
'scalar lr_pval = 1 - @cchisq(lr,1)