#! /bin/sh
######################################
##### Model Transformation Tools #####
######################################
# Bourne shell script: dm2fr_m
# Transformation: descriptor matrix to frequency response
# Copyright (c) P.J.Gawthrop, 1996.
###############################################################
## Version control history
###############################################################
## $Id$
## $Log$
## Revision 1.12 1998/09/02 12:02:14 peterg
## Added mttinput paramater
##
## Revision 1.11 1998/08/11 13:32:42 peterg
## Lowercase mttLAST etc
##
## Revision 1.10 1998/07/27 20:27:25 peterg
## Now get parameters for simpar file.
##
## Revision 1.9 1998/02/26 15:12:26 peterg
## Removed parameter stuff
##
# Revision 1.8 1996/08/30 14:54:36 peter
# Took back lock.
#
## Revision 1.7 1996/08/24 14:23:00 peter
## Global parameter passing.
## Proper error handling.
#
## Revision 1.6 1996/08/16 14:26:07 peter
## Fixed multi-output bug.
## Made sure that u0 is ok.
##
## Revision 1.5 1996/08/15 16:23:02 peter
## Now uses W in place of w for consistancy with time responses.
##
## Revision 1.4 1996/08/15 11:52:42 peter
## Now creats a number of versions:
## fr complex frequency response
## lmfr log magnitude of fr
## lpfr phase of fr
## nyfr real and imag parts - Nyquist style
## nifr Nichols style.
##
## Revision 1.3 1996/08/11 19:08:08 peter
## Parameter passing now enabled.
##
## Revision 1.2 1996/08/11 09:32:12 peter
## Now takes the numpar parameters correctly
##
## Revision 1.1 1996/08/10 14:11:11 peter
## Initial revision
##
###############################################################
echo Creating $1_fr.m
echo Creating $1_lmfr.m
echo Creating $1_lpfr.m
echo Creating $1_nyfr.m
echo Creating $1_nifr.m
#if [ "$2" = "" ];
#then
# PARAMS='W=logspace(-1,2,100); u0=zeros(nu,1); u0(1)=1;'
# echo Using default parameter $PARAMS
#else
# PARAMS=$2;
#fi
$MATRIX << EOF > dm2fr_m.log 2>mtt_error.txt
# Data
$1_numpar;
# Simulation parameters
$1_simpar;
[nx,ny,nu,nz,nyz] = $1_def
%Defaults
if exist('mttwmin')==0
mttwmin = -1;
end;
if exist('mttwmax')==0
mttwmax = 2;
end;
if exist('mttwsteps')==0
mttwsteps = 100;
end;
W = logspace(mttwmin,mttwmax,mttwsteps)';
if exist('mttinput')==0
mttinput = 1;
end;
mttu0 = zeros(nu,1);
mttu0(mttinput) = 1;
[n,m]=size(W);
if m>n
W=W';
end;
[n,m]=size(mttu0);
if m>n
mttu0=mttu0';
end;
[A,B,C,D,E] = $1_dm;
fr = dm2fr(A,B,C,D,E,W,mttu0);
lw = log10(W);
lmfr = log10(abs(fr));
pfr = angle(fr)*180/pi;
% Complex frequency response
write_matrix([W fr], '$1_fr');
% Log magnitude v log frequency
write_matrix([lw lmfr], '$1_lmfr');
% Angle v log frequency
write_matrix([lw pfr], '$1_lpfr');
% Nyquist style
re = real(fr);
im = imag(fr);
nyq = [re(:,1) im(:,1)];
for i = 2:ny
nyq = [nyq re(:,i) im(:,i)];
end;
write_matrix(nyq, '$1_nyfr');
% Nichols style
re = lmfr;
im = pfr;
nic = [im(:,1) re(:,1)];
for i = 2:ny
nic = [nic im(:,i) re(:,i)];
end;
write_matrix(nic, '$1_nifr');
EOF
# Now invoke the standard error handling.
mtt_error mtt_error.txt