Econ 240C

Econ 240C Lecture 17

Part I. VAR • Does the Federal Funds Rate Affect Capacity Utilization?

The Federal Funds Rate is one of the principal monetary instruments of the Federal Reserve • Does it affect the economy in “real terms”, as measured by capacity utilization

Preliminary Analysis

The Time Series, Monthly, Jan uary 1967through May 2003

Changes in FFR & Capacity Utilization

Contemporaneous Correlation

Dynamics: Cross-correlation

Granger Causality

Estimation of VAR

Estimation Results • OLS Estimation • each series is positively autocorrelated • lags 1 and 24 for dcapu • lags 1, 2, 7, 9, 13, 16 • each series depends on the other • dcapu on dffr: negatively at lags 10, 12, 17, 21 • dffr on dcapu: positively at lags 1, 2, 9, 10 and negatively at lag 12

Correlogram of DFFR

Correlogram of DCAPU

We Have Mutual Causality, But We Already Knew That DCAPU DFFR

Interpretation • We need help • Rely on assumptions

What If • What if there were a pure shock to dcapu • as in the primitive VAR, a shock that only affects dcapu immediately

Primitive VAR

The Logic of What If • A shock, edffr , to dffr affects dffr immediately, but if dcapu depends contemporaneously on dffr, then this shock will affect it immediately too • so assume b1 iszero, then dcapu depends only on its own shock, edcapu , first period • But we are not dealing with the primitive, but have substituted out for the contemporaneous terms • Consequently, the errors are no longer pure but have to be assumed pure

DCAPU shock DFFR

Standard VAR • dcapu(t) = (a1 + b1 a2)/(1- b1 b2) +[ (g11+ b1 g21)/(1- b1 b2)] dcapu(t-1) + [ (g12+ b1 g22)/(1- b1 b2)] dffr(t-1) + [(d1+ b1 d2 )/(1- b1 b2)] x(t) + (edcapu(t) + b1 edffr(t))/(1- b1 b2) • But if we assume b1 =0, • thendcapu(t) = a1 +g11 dcapu(t-1) + g12 dffr(t-1) + d1 x(t) + edcapu(t) +

Note that dffr still depends on both shocks • dffr(t) = (b2 a1 + a2)/(1- b1 b2) +[(b2 g11+ g21)/(1- b1 b2)] dcapu(t-1) + [ (b2 g12+ g22)/(1- b1 b2)] dffr(t-1) + [(b2 d1+ d2 )/(1- b1 b2)] x(t) + (b2edcapu(t) + edffr(t))/(1- b1 b2) • dffr(t) = (b2 a1 + a2)+[(b2 g11+ g21) dcapu(t-1) + (b2 g12+ g22) dffr(t-1) + (b2 d1+ d2 ) x(t) + (b2edcapu(t) + edffr(t))

Reality edcapu(t) DCAPU shock DFFR edffr(t)

What If edcapu(t) DCAPU shock DFFR edffr(t)

EVIEWS

Interpretations • Response of dcapu to a shock in dcapu • immediate and positive: autoregressive nature • Response of dffr to a shock in dffr • immediate and positive: autoregressive nature • Response of dcapu to a shock in dffr • starts at zero by assumption that b1 =0, • interpret as Fed having no impact on CAPU • Response of dffr to a shock in dcapu • positive and then damps out • interpret as Fed raising FFR if CAPU rises

Change the Assumption Around

What If edcapu(t) DCAPU shock DFFR edffr(t)

Standard VAR • dffr(t) = (b2 a1 + a2)/(1- b1 b2) +[(b2 g11+ g21)/(1- b1 b2)] dcapu(t-1) + [ (b2 g12+ g22)/(1- b1 b2)] dffr(t-1) + [(b2 d1+ d2 )/(1- b1 b2)] x(t) + (b2edcapu(t) + edffr(t))/(1- b1 b2) • if b2 = 0 • then, dffr(t) = a2 + g21 dcapu(t-1) + g22 dffr(t-1) + d2 x(t) + edffr(t)) • but, dcapu(t) = (a1 + b1 a2) + (g11+ b1 g21) dcapu(t-1) + [ (g12+ b1 g22) dffr(t-1) + [(d1+ b1 d2 ) x(t) + (edcapu(t) + b1 edffr(t))

Interpretations • Response of dcapu to a shock in dcapu • immediate and positive: autoregressive nature • Response of dffr to a shock in dffr • immediate and positive: autoregressive nature • Response of dcapu to a shock in dffr • is positive (not - ) initially but then damps to zero • interpret as Fed having no or little control of CAPU • Response of dffr to a shock in dcapu • starts at zero by assumption that b2 =0, • interpret as Fed raising FFR if CAPU rises

Conclusions • We come to the same model interpretation and policy conclusions no matter what the ordering, i.e. no matter which assumption we use, b1 =0, or b2 =0. • So, accept the analysis

Understanding through Simulation • We can not get back to the primitive fron the standard VAR, so we might as well simplify notation • y(t) = (a1 + b1 a2)/(1- b1 b2) +[ (g11+ b1 g21)/(1- b1 b2)] y(t-1) + [ (g12+ b1 g22)/(1- b1 b2)] w(t-1) + [(d1+ b1 d2 )/(1- b1 b2)] x(t) + (edcapu(t) + b1 edffr(t))/(1- b1 b2) • becomes y(t) = a1 + b11 y(t-1) + c11 w(t-1) + d1 x(t) + e1(t)

And w(t) = (b2 a1 + a2)/(1- b1 b2) +[(b2 g11+ g21)/(1- b1 b2)] y(t-1) + [ (b2 g12+ g22)/(1- b1 b2)] w(t-1) + [(b2 d1+ d2 )/(1- b1 b2)] x(t) + (b2edcapu(t) + edffr(t))/(1- b1 b2) • becomes w(t) = a2 + b21 y(t-1) + c21 w(t-1) + d2 x(t) + e2(t)

Numerical Example y(t) = 0.7 y(t-1) + 0.2 w(t-1)+ e1(t) w(t) = 0.2 y(t-1) + 0.7 w(t-1) + e2(t) where e1(t) = ey(t) + 0.8 ew(t) e2(t) = ew(t)

Generate ey(t) and ew(t) as white noise processes using nrnd and where ey(t) and ew(t) are independent. Scale ey(t) so that the variances of e1(t) and e2(t) are equal • ey(t) = 0.6 *nrnd and • ew(t) = nrnd (different nrnd) • Note the correlation of e1(t) and e2(t) is 0.8

Analytical Solution Is Possible • These numerical equations for y(t) and w(t) could be solved for y(t) as a distributed lag of e1(t) and a distributed lag of e2(t), or, equivalently, as a distributed lag of ey(t) and a distributed lag of ew(t) • However, this is an example where simulation is easier

Simulated Errors e1(t) and e2(t)

Estimated Model

Econ 240C

Econ 240C

Presentation Transcript

ECON 240C

Econ 240C

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Econ 240C

Econ 240C

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Econ 240C

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Econ 240C

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Econ 240C

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