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# difference equations in MATLAB - why the need to switch signs?

Perhaps this is more of a math question than a MATLAB one, not really sure. I'm using MATLAB to compute an economic model - the New Hybrid ISLM model - and there's a confusing step where the author switches the sign of the solution.

First, the author declares symbolic variables and sets up a system of difference equations. Note that the suffixes "a" and "2t" both mean "time t+1", "2a" means "time t+2" and "t" means "time t":

``````   %% --------------------------[2] MODEL proc-----------------------------%%
% Define endogenous vars  ('a' denotes t+1 values)
syms  y2a  pi2a  ya  pia  va  y2t pi2t yt pit vt  ;
% Monetary policy rule
ia = q1*ya+q2*pia;
%  ia = q1*(ya-yt)+q2*pia;  %%option speed limit policy
% Model equations
IS   = rho*y2a+(1-rho)*yt-sigma*(ia-pi2a)-ya;
AS   = beta*pi2a+(1-beta)*pit+alpha*ya-pia+va;
dum1 = ya-y2t;
dum2 = pia-pi2t;
MPs  = phi*vt-va;

optcon  = [IS ; AS ; dum1 ; dum2; MPs];
``````

Edit: The equations that are going into the matrix, as they would appear in a textbook are as follows (curly braces indicate time period values, greek letters are parameters):

First equation:

``````y{t+1} = rho*y{t+2} + (1-rho)*y{t} - sigma*(i{t+1}-pi{t+2})
``````

Second equation:

``````pi{t+1} = beta*pi{t+2} + (1-beta)*pi{t} + alpha*y{t+1} + v{t+1}
``````

Third and fourth are dummies:

``````y{t+1} = y{t+1}
pi{t+1} = pi{t+1}
``````

Fifth is simple:

``````v{t+1} = phi*v{t}
``````

Moving on, the author computes the matrix A:

``````    %% ------------------  [3] Linearization proc  ------------------------%%
% Differentiation
xx = [y2a  pi2a  ya  pia  va  y2t pi2t yt pit vt] ; % define vars
jopt = jacobian(optcon,xx);

% Define Linear Coefficients
coef = eval(jopt);

B =  [ -coef(:,1:5)  ] ;
C =  [  coef(:,6:10)  ] ;
% B[c(t+1)  l(t+1)  k(t+1)  z(t+1)] = C[c(t)  l(t)  k(t)  z(t)]
A = inv(C)*B ; %(Linearized reduced form )
``````

As far as I understand, this A is the solution to the system. It's the matrix that turns time t+1 and t+2 variables into t and t+1 variables (it's a forward-looking model). My question is essentially why is it necessary to reverse the signs of all the partial derivatives in B in order to get this solution? I'm talking about this step:

``````B =  [ -coef(:,1:5)  ] ;
``````

Reversing the sign here obviously reverses the sign of every component of A, but I don't have a clear understanding of why it's necessary. My apologies if the question is unclear or if this isn't the best place to ask.

-
Can you supply the equations you're trying to solve in a more readable format? IE, not the matlab code itself but just the model as it would appear in a textbook. – Marc May 20 '10 at 13:20
I just updated the post to include the equations, hope that makes it easier to understand. Thanks a lot for taking a look. – jefflovejapan May 20 '10 at 15:24
do you get different answers if you do not switch sign? – Anycorn May 20 '10 at 22:01
Yes, since A=inv(C)*B the sign of every element of A gets reversed if you don't switch the sign of B. – jefflovejapan May 20 '10 at 23:28