File mttroot/mtt/bin/trans/cse2rfe_r artifact 5e4feb17e7 part of check-in a0d28fdb76


#! /bin/sh

     ###################################### 
     ##### Model Transformation Tools #####
     ######################################

# Bourne shell script: cse2rfe_r
# Reduce  constrained-state equations to robot matrices
# Experimental version!
# State vector should have momenta in odd rows,angles in even;
# the last row should have the gravity velocity term.
# There should be one output (only) for each joint velocity.
# P.J.Gawthrop, Nov 92, Dec 93, May 1994
# Copyright (c) P.J.Gawthrop, 1992, May 1994.

###############################################################
## Version control history
###############################################################
## $Id$
## $Log$
## Revision 1.2  1996/12/05 12:10:00  peterg
## Version history added.
##
###############################################################

# Inform user
echo Creating $1_rfe.r

# Remove the old log file
rm -f cse2rfe_r.log

# Use reduce to accomplish the transformation
reduce >cse2rfe_r.log << EOF

IN "$1_def.r";
IN "$1_sympar.r";
IN "$1_csm.r";
IN "$1_cse.r";

MTTN2 := MTTNy;


%Find E11 and E12 matrices
MATRIX MTTE11(MTTN2,MTTN2), MTTE12(MTTN2,MTTN2);
FOR i := 1:MTTN2 DO
  FOR j := 1:MTTN2 DO
  BEGIN
    MTTE11(i,j) := MTTE(2*i-1,2*j-1);
    MTTE12(i,j) := MTTE(2*i-1,2*j);
  END;

%Find inertia matrix
MATRIX MTTImi(MTTN2,MTTN2);
FOR i := 1:MTTN2 DO
  BEGIN
    MTTImi(i,i) := MTTC(i,2*i-1);
   END;

MTTIm := MTTImi^-1;

%Find gravity matrix if there is an extra gravity state
MATRIX MTTG(MTTN2,1);
MTTNy2 := 2*MTTNy;
IF ( (MTTNx-1)/MTTNy2 = 1) THEN
FOR i := 1:MTTN2 DO
  BEGIN
    MTTG(i,1) := MTTE(2*i-1,MTTNx);
   END;



%Find V matrix from RHS of equation
MTTu1 := 0;
MTTu2 := 0;
MTTu3 := 0;
MTTu4 := 0;
MTTu5 := 0;
MTTu6 := 0;

MTTx2 := theta_1;
MTTx4 := theta_2;
MTTx6 := theta_3;
MTTx8 := theta_4;
MTTx10 := theta_5;
MTTx12 := theta_6;

MTTx1 := dot_theta_1*MTTIm(1,1);
MTTx3 := dot_theta_2*MTTIm(2,2);
MTTx5 := dot_theta_3*MTTIm(2,3);

MATRIX MTTdt(6,1);
MTTdt(1,1) := dot_theta_1;
MTTdt(2,1) := dot_theta_2;
MTTdt(3,1) := dot_theta_3;
MTTdt(4,1) := dot_theta_4;
MTTdt(5,1) := dot_theta_5;
MTTdt(6,1) := dot_theta_6;

MATRIX dtheta(MTTN2,1);
FOR i := 1:MTTN2 DO
  BEGIN
    dtheta(i,1) := MTTdt(i,1);
   END;

MATRIX MTTVrhs(MTTN2,1);
MATRIX MTTV(MTTN2,1);
FOR i := 1:MTTN2 DO
  BEGIN
    MTTVrhs(i,1) := MTTEdX(2*i-1,1);
   END;

%Find V matrix 
MTTV := MTTE12*dtheta - MTTVrhs;

%Find C matrix
MATRIX MTTC(MTTN2,MTTN2);
k := 0;
FOR i := 1:MTTN2 DO
  FOR j := 1:MTTN2 DO
  BEGIN
  coeffs := coeff(MTTV(i,1),MTTdt(j,1));
  IF length(coeffs)>2 THEN co := part(coeffs,3) ELSE co := 0;
  MTTC(i,j) := co;
  END;

%Find B matrix
MTTN3 := MTTN2*(MTTN2-1)/2;

IF MTTN3>0 THEN
BEGIN
MATRIX MTTB(MTTN2,MTTN3);
FOR i := 1:MTTN2 DO
BEGIN
  counter := 0;
  FOR j := 1:MTTN2-1 DO
  BEGIN
  coeffs := coeff(MTTV(i,1),MTTdt(j,1));
  IF length(coeffs)>1 THEN co := part(coeffs,2) ELSE co := 0;
    FOR k := j+1:MTTN2 DO
    BEGIN 
    counter := counter+1;
    coeffs2 := coeff(co,MTTdt(k,1));
    IF length(coeffs2)>1 THEN co2 := part(coeffs2,2) ELSE co2 := 0;
     MTTB(i,counter) := co2;
    END;
  END;
END;
END;

OFF Echo;
OFF Nat;
ON NERO;

OUT "$1_rfe.r";

%% M
write "MATRIX MTTM(", MTTN2, ",", MTTN2, ")";
MTTM := MTTE11*MTTIm;

%% V
write "MATRIX MTTRV(", MTTN2, ",1)";
MTTRV := MTTV;

%% 

write "MATRIX MTTRC(", MTTN2, ",", MTTN2, ")";
MTTRC := MTTC;

IF MTTN3>0 THEN
  BEGIN
  write "MATRIX MTTRB(", MTTN2, ",", MTTN3, ")";
  MTTRB := MTTRB;
END;

write "MATRIX MTTRG(", MTTN2, ", 1)";
MTTRG := MTTG;

write ";END;"$
SHUT "$1_rfe.r";
quit;
EOF


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