function [Comb] =  Comb_abg
# This function is the acausal bond graph representation of Comb
# Generated by MTT on Thu Mar 16 10:33:30 2000
# The file is in Octave format

# Subsystems and Ports

# Port Hydraulic_in
  Comb.ports.Hydraulic_in.type = "SS";
  Comb.ports.Hydraulic_in.cr = "SS";
  Comb.ports.Hydraulic_in.arg = "external,external";
  Comb.ports.Hydraulic_in.repetitions = 1;
  Comb.ports.Hydraulic_in.status = -1;
  Comb.ports.Hydraulic_in.connections = [-3 ];

# Port Hydraulic_out
  Comb.ports.Hydraulic_out.type = "SS";
  Comb.ports.Hydraulic_out.cr = "SS";
  Comb.ports.Hydraulic_out.arg = "external,external";
  Comb.ports.Hydraulic_out.repetitions = 1;
  Comb.ports.Hydraulic_out.status = -1;
  Comb.ports.Hydraulic_out.connections = [7 ];

# Port Heat
  Comb.ports.Heat.type = "SS";
  Comb.ports.Heat.cr = "SS";
  Comb.ports.Heat.arg = "external,external";
  Comb.ports.Heat.repetitions = 1;
  Comb.ports.Heat.status = -1;
  Comb.ports.Heat.connections = [-5 ];

# Port Thermal_in
  Comb.ports.Thermal_in.type = "SS";
  Comb.ports.Thermal_in.cr = "SS";
  Comb.ports.Thermal_in.arg = "external,external";
  Comb.ports.Thermal_in.repetitions = 1;
  Comb.ports.Thermal_in.status = -1;
  Comb.ports.Thermal_in.connections = [-2 ];

# Port Thermal_out
  Comb.ports.Thermal_out.type = "SS";
  Comb.ports.Thermal_out.cr = "SS";
  Comb.ports.Thermal_out.arg = "external,external";
  Comb.ports.Thermal_out.repetitions = 1;
  Comb.ports.Thermal_out.status = -1;
  Comb.ports.Thermal_out.connections = [6 ];

# Component P
  Comb.subsystems.P.type = "SS";
  Comb.subsystems.P.cr = "SS";
  Comb.subsystems.P.arg = "external,0";
  Comb.subsystems.P.repetitions = 1;
  Comb.subsystems.P.status = -1;
  Comb.subsystems.P.connections = [9 ];

# Component T
  Comb.subsystems.T.type = "SS";
  Comb.subsystems.T.cr = "SS";
  Comb.subsystems.T.arg = "external,0";
  Comb.subsystems.T.repetitions = 1;
  Comb.subsystems.T.status = -1;
  Comb.subsystems.T.connections = [8 ];

# Component pipe
  Comb.subsystems.pipe.type = "hPipe";
  Comb.subsystems.pipe.cr = "none";
  Comb.subsystems.pipe.arg = "m_c;v_c;r";
  Comb.subsystems.pipe.repetitions = 1;
  Comb.subsystems.pipe.status = -1;
  Comb.subsystems.pipe.connections = [5 3 -4 2 -1 ];

# Component mtt1
  Comb.subsystems.mtt1.type = "0";
  Comb.subsystems.mtt1.cr = "";
  Comb.subsystems.mtt1.arg = "";
  Comb.subsystems.mtt1.repetitions = 1;
  Comb.subsystems.mtt1.status = -1;
  Comb.subsystems.mtt1.connections = [1 -6 -8 ];

# Component mtt2
  Comb.subsystems.mtt2.type = "0";
  Comb.subsystems.mtt2.cr = "";
  Comb.subsystems.mtt2.arg = "";
  Comb.subsystems.mtt2.repetitions = 1;
  Comb.subsystems.mtt2.status = -1;
  Comb.subsystems.mtt2.connections = [4 -7 -9 ];

# Ordered list of Port names
  Comb.portlist(1,:) = "Hydraulic_in ";
  Comb.portlist(2,:) = "Hydraulic_out";
  Comb.portlist(3,:) = "Heat         ";
  Comb.portlist(4,:) = "Thermal_in   ";
  Comb.portlist(5,:) = "Thermal_out  ";

# Ordered list of subsystem names
  Comb.subsystemlist(1,:) = "P   ";
  Comb.subsystemlist(2,:) = "T   ";
  Comb.subsystemlist(3,:) = "pipe";
  Comb.subsystemlist(4,:) = "mtt1";
  Comb.subsystemlist(5,:) = "mtt2";

# Bonds 
  Comb.bonds = [
      0 0 
      0 0 
      0 0 
      0 0 
      0 0 
      0 0 
      0 0 
      1 1 
      1 1 
      ];

# Aliases 
# A double underscore __ represents a comma 
Comb.alias.out = "Thermal_out,Hydraulic_out";
Comb.alias.Hy_out = "Hydraulic_out";
Comb.alias.v_c = "$2";
Comb.alias.Th_in = "Thermal_in";
Comb.alias.r = "$3";
Comb.alias.Th_out = "Thermal_out";
Comb.alias.in = "Thermal_in,Hydraulic_in";
Comb.alias.Hy_in = "Hydraulic_in";
Comb.alias.m_c = "$1";

function [Density] =  Density_abg
# This function is the acausal bond graph representation of Density
# Generated by MTT on Thu Mar 16 10:36:39 2000
# The file is in Octave format

# Subsystems and Ports

# Port Pressure
  Density.ports.Pressure.type = "SS";
  Density.ports.Pressure.cr = "SS";
  Density.ports.Pressure.arg = "external,external";
  Density.ports.Pressure.repetitions = 1;
  Density.ports.Pressure.status = -1;
  Density.ports.Pressure.connections = [-4 ];

# Port Temperature
  Density.ports.Temperature.type = "SS";
  Density.ports.Temperature.cr = "SS";
  Density.ports.Temperature.arg = "external,external";
  Density.ports.Temperature.repetitions = 1;
  Density.ports.Temperature.status = -1;
  Density.ports.Temperature.connections = [-5 ];

# Port Density
  Density.ports.Density.type = "SS";
  Density.ports.Density.cr = "SS";
  Density.ports.Density.arg = "external,external";
  Density.ports.Density.repetitions = 1;
  Density.ports.Density.status = -1;
  Density.ports.Density.connections = [3 ];

# Component r
  Density.subsystems.r.type = "R";
  Density.subsystems.r.cr = "Density";
  Density.subsystems.r.arg = "density,ideal_gas,r";
  Density.subsystems.r.repetitions = 1;
  Density.subsystems.r.status = -1;
  Density.subsystems.r.connections = [1 2 -3 ];

# Component mtt1
  Density.subsystems.mtt1.type = "AE";
  Density.subsystems.mtt1.cr = "";
  Density.subsystems.mtt1.arg = "";
  Density.subsystems.mtt1.repetitions = 1;
  Density.subsystems.mtt1.status = -1;
  Density.subsystems.mtt1.connections = [4 -1 ];

# Component mtt2
  Density.subsystems.mtt2.type = "AE";
  Density.subsystems.mtt2.cr = "";
  Density.subsystems.mtt2.arg = "";
  Density.subsystems.mtt2.repetitions = 1;
  Density.subsystems.mtt2.status = -1;
  Density.subsystems.mtt2.connections = [5 -2 ];

# Ordered list of Port names
  Density.portlist(1,:) = "Pressure   ";
  Density.portlist(2,:) = "Temperature";
  Density.portlist(3,:) = "Density    ";

# Ordered list of subsystem names
  Density.subsystemlist(1,:) = "r   ";
  Density.subsystemlist(2,:) = "mtt1";
  Density.subsystemlist(3,:) = "mtt2";

# Bonds 
  Density.bonds = [
      1 1 
      1 1 
      1 1 
      0 0 
      0 0 
      ];

# Aliases 
# A double underscore __ represents a comma 
Density.alias.P = "Pressure";
Density.alias.out = "Density";
Density.alias.rho = "Density";
Density.alias.T = "Temperature";
Density.alias.density__ideal_gas__r = "$1";

% Constitutive relation file for Density (Density_cr.r)
% Generated by MTT at Wed Mar 11 11:01:28 GMT 1998

OPERATOR Density;

% Ideal gas
FOR ALL R,Temperature,Pressure,Nothing
LET Density(density,ideal_gas,R,effort,3,
	Pressure,effort,1,
	Temperature,effort,2,
	Nothing,flow,3
	) = Pressure/(R*Temperature);

FOR ALL R,Temperature,Pressure,Nothing
LET Density(specific_volume,ideal_gas,R,effort,3,
	Pressure,effort,1,
	Temperature,effort,2,
	Nothing,flow,3
	) = (R*Temperature)/Pressure;

% Incompressible
FOR ALL rho,Temperature,Pressure,Nothing
LET Density(density,incompressible,rho,effort,3,
	Pressure,effort,1,
	Temperature,effort,2,
	Nothing,flow,3
	) = rho;

FOR ALL rho,Temperature,Pressure,Nothing
LET Density(specific_volume,incompressible,rho,effort,3,
	Pressure,effort,1,
	Temperature,effort,2,
	Nothing,flow,3
	) = 1/rho;

END;

function [In] =  In_abg
# This function is the acausal bond graph representation of In
# Generated by MTT on Thu Mar 16 10:33:58 2000
# The file is in Octave format

# Subsystems and Ports

# Port Hy_out
  In.ports.Hy_out.type = "SS";
  In.ports.Hy_out.cr = "SS";
  In.ports.Hy_out.arg = "external,external";
  In.ports.Hy_out.repetitions = 1;
  In.ports.Hy_out.status = -1;
  In.ports.Hy_out.connections = [2 ];

# Port Th_out
  In.ports.Th_out.type = "SS";
  In.ports.Th_out.cr = "SS";
  In.ports.Th_out.arg = "external,external";
  In.ports.Th_out.repetitions = 1;
  In.ports.Th_out.status = -1;
  In.ports.Th_out.connections = [1 ];

# Component Hy_in
  In.subsystems.Hy_in.type = "SS";
  In.subsystems.Hy_in.cr = "SS";
  In.subsystems.Hy_in.arg = "p_1,internal";
  In.subsystems.Hy_in.repetitions = 1;
  In.subsystems.Hy_in.status = -1;
  In.subsystems.Hy_in.connections = [-2 ];

# Component Th_in
  In.subsystems.Th_in.type = "SS";
  In.subsystems.Th_in.cr = "SS";
  In.subsystems.Th_in.arg = "t_1,internal";
  In.subsystems.Th_in.repetitions = 1;
  In.subsystems.Th_in.status = -1;
  In.subsystems.Th_in.connections = [-1 ];

# Ordered list of Port names
  In.portlist(1,:) = "Hy_out";
  In.portlist(2,:) = "Th_out";

# Ordered list of subsystem names
  In.subsystemlist(1,:) = "Hy_in";
  In.subsystemlist(2,:) = "Th_in";

# Bonds 
  In.bonds = [
      1 1 
      1 1 
      ];

# Aliases 
# A double underscore __ represents a comma 
In.alias.out = "Th_out,Hy_out";
In.alias.in = "Th_out,Hy_out";

% Verbal description for system In (In_desc.tex)
% Generated by MTT on Tue Jan 13 18:02:36 GMT 1998.

% %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
% %% Version control history
% %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
% %% $Id$
% %% $Log$
% %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%

   The acausal bond graph of system \textbf{In} is
   displayed in Figure \Ref{In_abg} and its label
   file is listed in Section \Ref{sec:In_lbl}.
   The subsystems are listed in Section \Ref{sec:In_sub}.

function [Load] =  Load_abg
# This function is the acausal bond graph representation of Load
# Generated by MTT on Thu Mar 16 10:34:27 2000
# The file is in Octave format

# Subsystems and Ports

# Port in
  Load.ports.in.type = "SS";
  Load.ports.in.cr = "SS";
  Load.ports.in.arg = "external,external";
  Load.ports.in.repetitions = 1;
  Load.ports.in.status = -1;
  Load.ports.in.connections = [-1 ];

# Port out
  Load.ports.out.type = "SS";
  Load.ports.out.cr = "SS";
  Load.ports.out.arg = "external,external";
  Load.ports.out.repetitions = 1;
  Load.ports.out.status = -1;
  Load.ports.out.connections = [3 ];

# Component PowerSensor
  Load.subsystems.PowerSensor.type = "PS";
  Load.subsystems.PowerSensor.cr = "";
  Load.subsystems.PowerSensor.arg = "";
  Load.subsystems.PowerSensor.repetitions = 1;
  Load.subsystems.PowerSensor.status = -1;
  Load.subsystems.PowerSensor.connections = [1 -2 -3 ];

# Component r_l
  Load.subsystems.r_l.type = "R";
  Load.subsystems.r_l.cr = "lin";
  Load.subsystems.r_l.arg = "flow,r_l";
  Load.subsystems.r_l.repetitions = 1;
  Load.subsystems.r_l.status = -1;
  Load.subsystems.r_l.connections = [2 ];

# Ordered list of Port names
  Load.portlist(1,:) = "in ";
  Load.portlist(2,:) = "out";

# Ordered list of subsystem names
  Load.subsystemlist(1,:) = "PowerSensor";
  Load.subsystemlist(2,:) = "r_l        ";

# Bonds 
  Load.bonds = [
      0 0 
      0 0 
      0 0 
      ];

# Aliases 
# A double underscore __ represents a comma 
Load.alias.out = "out";
Load.alias.r_l = "$2";
Load.alias.in = "in";
Load.alias.PowerSensor = "$1";

function [Out] =  Out_abg
# This function is the acausal bond graph representation of Out
# Generated by MTT on Thu Mar 16 10:34:51 2000
# The file is in Octave format

# Subsystems and Ports

# Port Hy_in
  Out.ports.Hy_in.type = "SS";
  Out.ports.Hy_in.cr = "SS";
  Out.ports.Hy_in.arg = "external,external";
  Out.ports.Hy_in.repetitions = 1;
  Out.ports.Hy_in.status = -1;
  Out.ports.Hy_in.connections = [-1 ];

# Port Th_in
  Out.ports.Th_in.type = "SS";
  Out.ports.Th_in.cr = "SS";
  Out.ports.Th_in.arg = "external,external";
  Out.ports.Th_in.repetitions = 1;
  Out.ports.Th_in.status = -1;
  Out.ports.Th_in.connections = [-2 ];

# Component Hy_out
  Out.subsystems.Hy_out.type = "SS";
  Out.subsystems.Hy_out.cr = "SS";
  Out.subsystems.Hy_out.arg = "p_1,internal";
  Out.subsystems.Hy_out.repetitions = 1;
  Out.subsystems.Hy_out.status = -1;
  Out.subsystems.Hy_out.connections = [1 ];

# Component Th_out
  Out.subsystems.Th_out.type = "SS";
  Out.subsystems.Th_out.cr = "SS";
  Out.subsystems.Th_out.arg = "t_1,internal";
  Out.subsystems.Th_out.repetitions = 1;
  Out.subsystems.Th_out.status = -1;
  Out.subsystems.Th_out.connections = [2 ];

# Ordered list of Port names
  Out.portlist(1,:) = "Hy_in";
  Out.portlist(2,:) = "Th_in";

# Ordered list of subsystem names
  Out.subsystemlist(1,:) = "Hy_out";
  Out.subsystemlist(2,:) = "Th_out";

# Bonds 
  Out.bonds = [
      -1 -1 
      -1 -1 
      ];

# Aliases 
# A double underscore __ represents a comma 
Out.alias.in = "Th_in,Hy_in";

% Verbal description for system Out (Out_desc.tex)
% Generated by MTT on Tue Jan 13 18:02:44 GMT 1998.

% %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
% %% Version control history
% %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
% %% $Id$
% %% $Log$
% %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%

   The acausal bond graph of system \textbf{Out} is
   displayed in Figure \Ref{Out_abg} and its label
   file is listed in Section \Ref{sec:Out_lbl}.
   The subsystems are listed in Section \Ref{sec:Out_sub}.

function [Poly] =  Poly_abg
# This function is the acausal bond graph representation of Poly
# Generated by MTT on Thu Mar 16 10:35:48 2000
# The file is in Octave format

# Subsystems and Ports

# Port Pressure_1
  Poly.ports.Pressure_1.type = "SS";
  Poly.ports.Pressure_1.cr = "SS";
  Poly.ports.Pressure_1.arg = "external,external";
  Poly.ports.Pressure_1.repetitions = 1;
  Poly.ports.Pressure_1.status = -1;
  Poly.ports.Pressure_1.connections = [-2 ];

# Port Temperature_1
  Poly.ports.Temperature_1.type = "SS";
  Poly.ports.Temperature_1.cr = "SS";
  Poly.ports.Temperature_1.arg = "external,external";
  Poly.ports.Temperature_1.repetitions = 1;
  Poly.ports.Temperature_1.status = -1;
  Poly.ports.Temperature_1.connections = [-6 ];

# Port Pressure_2
  Poly.ports.Pressure_2.type = "SS";
  Poly.ports.Pressure_2.cr = "SS";
  Poly.ports.Pressure_2.arg = "external,external";
  Poly.ports.Pressure_2.repetitions = 1;
  Poly.ports.Pressure_2.status = -1;
  Poly.ports.Pressure_2.connections = [-4 ];

# Port Temperature_2
  Poly.ports.Temperature_2.type = "SS";
  Poly.ports.Temperature_2.cr = "SS";
  Poly.ports.Temperature_2.arg = "external,external";
  Poly.ports.Temperature_2.repetitions = 1;
  Poly.ports.Temperature_2.status = -1;
  Poly.ports.Temperature_2.connections = [8 ];

# Component r
  Poly.subsystems.r.type = "R";
  Poly.subsystems.r.cr = "Poly";
  Poly.subsystems.r.arg = "alpha";
  Poly.subsystems.r.repetitions = 1;
  Poly.subsystems.r.status = -1;
  Poly.subsystems.r.connections = [1 3 5 -7 ];

# Component zero
  Poly.subsystems.zero.type = "SS";
  Poly.subsystems.zero.cr = "SS";
  Poly.subsystems.zero.arg = "0,0";
  Poly.subsystems.zero.repetitions = 1;
  Poly.subsystems.zero.status = -1;
  Poly.subsystems.zero.connections = [-9 ];

# Component mtt1
  Poly.subsystems.mtt1.type = "AE";
  Poly.subsystems.mtt1.cr = "";
  Poly.subsystems.mtt1.arg = "";
  Poly.subsystems.mtt1.repetitions = 1;
  Poly.subsystems.mtt1.status = -1;
  Poly.subsystems.mtt1.connections = [2 -1 ];

# Component mtt2
  Poly.subsystems.mtt2.type = "AE";
  Poly.subsystems.mtt2.cr = "";
  Poly.subsystems.mtt2.arg = "";
  Poly.subsystems.mtt2.repetitions = 1;
  Poly.subsystems.mtt2.status = -1;
  Poly.subsystems.mtt2.connections = [4 -3 ];

# Component mtt3
  Poly.subsystems.mtt3.type = "AE";
  Poly.subsystems.mtt3.cr = "";
  Poly.subsystems.mtt3.arg = "";
  Poly.subsystems.mtt3.repetitions = 1;
  Poly.subsystems.mtt3.status = -1;
  Poly.subsystems.mtt3.connections = [6 -5 ];

# Component mtt4
  Poly.subsystems.mtt4.type = "1";
  Poly.subsystems.mtt4.cr = "";
  Poly.subsystems.mtt4.arg = "";
  Poly.subsystems.mtt4.repetitions = 1;
  Poly.subsystems.mtt4.status = -1;
  Poly.subsystems.mtt4.connections = [7 -8 9 ];

# Ordered list of Port names
  Poly.portlist(1,:) = "Pressure_1   ";
  Poly.portlist(2,:) = "Temperature_1";
  Poly.portlist(3,:) = "Pressure_2   ";
  Poly.portlist(4,:) = "Temperature_2";

# Ordered list of subsystem names
  Poly.subsystemlist(1,:) = "r   ";
  Poly.subsystemlist(2,:) = "zero";
  Poly.subsystemlist(3,:) = "mtt1";
  Poly.subsystemlist(4,:) = "mtt2";
  Poly.subsystemlist(5,:) = "mtt3";
  Poly.subsystemlist(6,:) = "mtt4";

# Bonds 
  Poly.bonds = [
      1 1 
      0 0 
      1 1 
      0 0 
      1 1 
      0 0 
      0 0 
      0 0 
      1 -1 
      ];

# Aliases 
# A double underscore __ represents a comma 
Poly.alias.out = "Temperature_2";
Poly.alias.P1 = "Pressure_1";
Poly.alias.P2 = "Pressure_2";
Poly.alias.T1 = "Temperature_1";
Poly.alias.T2 = "Temperature_2";
Poly.alias.alpha = "$1";

% Constitutive relation file for Poly (Poly_cr.r)
% Generated by MTT at Wed Mar 11 11:01:28 GMT 1998

OPERATOR Poly;

% Ideal gas

% Temperature output on port [T2]
FOR ALL alpha,P1,P2,T1,Nothing
LET Poly(alpha,effort,4,
	P1,effort,1,
	P2,effort,2,
	T1,effort,3,
	Nothing,flow,4
	) = T1*(P2/P1)^alpha;



END;

function [Pump] =  Pump_abg
# This function is the acausal bond graph representation of Pump
# Generated by MTT on Thu Mar 16 10:38:10 2000
# The file is in Octave format

# Subsystems and Ports

# Port Hydraulic_in
  Pump.ports.Hydraulic_in.type = "SS";
  Pump.ports.Hydraulic_in.cr = "SS";
  Pump.ports.Hydraulic_in.arg = "external,external";
  Pump.ports.Hydraulic_in.repetitions = 1;
  Pump.ports.Hydraulic_in.status = -1;
  Pump.ports.Hydraulic_in.connections = [-5 ];

# Port Hydraulic_out
  Pump.ports.Hydraulic_out.type = "SS";
  Pump.ports.Hydraulic_out.cr = "SS";
  Pump.ports.Hydraulic_out.arg = "external,external";
  Pump.ports.Hydraulic_out.repetitions = 1;
  Pump.ports.Hydraulic_out.status = -1;
  Pump.ports.Hydraulic_out.connections = [6 ];

# Port Shaft
  Pump.ports.Shaft.type = "SS";
  Pump.ports.Shaft.cr = "SS";
  Pump.ports.Shaft.arg = "external,external";
  Pump.ports.Shaft.repetitions = 1;
  Pump.ports.Shaft.status = -1;
  Pump.ports.Shaft.connections = [-12 ];

# Port Thermal_in
  Pump.ports.Thermal_in.type = "SS";
  Pump.ports.Thermal_in.cr = "SS";
  Pump.ports.Thermal_in.arg = "external,external";
  Pump.ports.Thermal_in.repetitions = 1;
  Pump.ports.Thermal_in.status = -1;
  Pump.ports.Thermal_in.connections = [-4 ];

# Port Thermal_out
  Pump.ports.Thermal_out.type = "SS";
  Pump.ports.Thermal_out.cr = "SS";
  Pump.ports.Thermal_out.arg = "external,external";
  Pump.ports.Thermal_out.repetitions = 1;
  Pump.ports.Thermal_out.status = -1;
  Pump.ports.Thermal_out.connections = [16 ];

# Component pipe
  Pump.subsystems.pipe.type = "wPipe";
  Pump.subsystems.pipe.cr = "none";
  Pump.subsystems.pipe.arg = "c_v;density,ideal_gas,r";
  Pump.subsystems.pipe.repetitions = 1;
  Pump.subsystems.pipe.status = -1;
  Pump.subsystems.pipe.connections = [3 -7 14 2 -1 ];

# Component poly
  Pump.subsystems.poly.type = "Poly";
  Pump.subsystems.poly.cr = "Poly";
  Pump.subsystems.poly.arg = "alpha";
  Pump.subsystems.poly.repetitions = 1;
  Pump.subsystems.poly.status = -1;
  Pump.subsystems.poly.connections = [9 8 11 -10 ];

# Component T
  Pump.subsystems.T.type = "SS";
  Pump.subsystems.T.cr = "SS";
  Pump.subsystems.T.arg = "external,0";
  Pump.subsystems.T.repetitions = 1;
  Pump.subsystems.T.status = -1;
  Pump.subsystems.T.connections = [17 ];

# Component k_p
  Pump.subsystems.k_p.type = "TF";
  Pump.subsystems.k_p.cr = "lin";
  Pump.subsystems.k_p.arg = "flow,k_p";
  Pump.subsystems.k_p.repetitions = 1;
  Pump.subsystems.k_p.status = -1;
  Pump.subsystems.k_p.connections = [13 -14 ];

# Component mtt1
  Pump.subsystems.mtt1.type = "0";
  Pump.subsystems.mtt1.cr = "";
  Pump.subsystems.mtt1.arg = "";
  Pump.subsystems.mtt1.repetitions = 1;
  Pump.subsystems.mtt1.status = -1;
  Pump.subsystems.mtt1.connections = [1 10 -15 -17 ];

# Component mtt2
  Pump.subsystems.mtt2.type = "0";
  Pump.subsystems.mtt2.cr = "";
  Pump.subsystems.mtt2.arg = "";
  Pump.subsystems.mtt2.repetitions = 1;
  Pump.subsystems.mtt2.status = -1;
  Pump.subsystems.mtt2.connections = [-6 7 -11 ];

# Component mtt3
  Pump.subsystems.mtt3.type = "0";
  Pump.subsystems.mtt3.cr = "";
  Pump.subsystems.mtt3.arg = "";
  Pump.subsystems.mtt3.repetitions = 1;
  Pump.subsystems.mtt3.status = -1;
  Pump.subsystems.mtt3.connections = [-3 5 -9 ];

# Component mtt4
  Pump.subsystems.mtt4.type = "0";
  Pump.subsystems.mtt4.cr = "";
  Pump.subsystems.mtt4.arg = "";
  Pump.subsystems.mtt4.repetitions = 1;
  Pump.subsystems.mtt4.status = -1;
  Pump.subsystems.mtt4.connections = [-2 4 -8 ];

# Component mtt5
  Pump.subsystems.mtt5.type = "EBTF";
  Pump.subsystems.mtt5.cr = "";
  Pump.subsystems.mtt5.arg = "";
  Pump.subsystems.mtt5.repetitions = 1;
  Pump.subsystems.mtt5.status = -1;
  Pump.subsystems.mtt5.connections = [15 -16 ];

# Component mtt6
  Pump.subsystems.mtt6.type = "1";
  Pump.subsystems.mtt6.cr = "";
  Pump.subsystems.mtt6.arg = "";
  Pump.subsystems.mtt6.repetitions = 1;
  Pump.subsystems.mtt6.status = -1;
  Pump.subsystems.mtt6.connections = [12 -13 ];

# Ordered list of Port names
  Pump.portlist(1,:) = "Hydraulic_in ";
  Pump.portlist(2,:) = "Hydraulic_out";
  Pump.portlist(3,:) = "Shaft        ";
  Pump.portlist(4,:) = "Thermal_in   ";
  Pump.portlist(5,:) = "Thermal_out  ";

# Ordered list of subsystem names
  Pump.subsystemlist(1,:) = "pipe";
  Pump.subsystemlist(2,:) = "poly";
  Pump.subsystemlist(3,:) = "T   ";
  Pump.subsystemlist(4,:) = "k_p ";
  Pump.subsystemlist(5,:) = "mtt1";
  Pump.subsystemlist(6,:) = "mtt2";
  Pump.subsystemlist(7,:) = "mtt3";
  Pump.subsystemlist(8,:) = "mtt4";
  Pump.subsystemlist(9,:) = "mtt5";
  Pump.subsystemlist(10,:) = "mtt6";

# Bonds 
  Pump.bonds = [
      0 0 
      0 0 
      0 0 
      0 0 
      0 0 
      0 0 
      0 0 
      0 0 
      0 0 
      0 0 
      0 0 
      -1 -1 
      0 0 
      0 0 
      0 0 
      0 0 
      1 1 
      ];

# Aliases 
# A double underscore __ represents a comma 
Pump.alias.out = "Thermal_out,Hydraulic_out";
Pump.alias.Hy_out = "Hydraulic_out";
Pump.alias.c_v = "$1";
Pump.alias.flow__k_p = "$4";
Pump.alias.Th_in = "Thermal_in";
Pump.alias.Th_out = "Thermal_out";
Pump.alias.Work = "Shaft";
Pump.alias.alpha = "$3";
Pump.alias.in = "Thermal_in,Hydraulic_in";
Pump.alias.Hy_in = "Hydraulic_in";
Pump.alias.density__ideal_gas__r = "$2";

function [SimpleGasTurbineABG] =  SimpleGasTurbineABG_abg
# This function is the acausal bond graph representation of SimpleGasTurbineABG
# Generated by MTT on Thu Mar 16 12:59:12 2000
# The file is in Octave format

# Subsystems and Ports

# Component c1
  SimpleGasTurbineABG.subsystems.c1.type = "Comb";
  SimpleGasTurbineABG.subsystems.c1.cr = "none";
  SimpleGasTurbineABG.subsystems.c1.arg = "m_c;v_c;r";
  SimpleGasTurbineABG.subsystems.c1.repetitions = 1;
  SimpleGasTurbineABG.subsystems.c1.status = -1;
  SimpleGasTurbineABG.subsystems.c1.connections = [14 -15 7 10 -11 ];

# Component j_s
  SimpleGasTurbineABG.subsystems.j_s.type = "I";
  SimpleGasTurbineABG.subsystems.j_s.cr = "lin";
  SimpleGasTurbineABG.subsystems.j_s.arg = "flow,j_s";
  SimpleGasTurbineABG.subsystems.j_s.repetitions = 1;
  SimpleGasTurbineABG.subsystems.j_s.status = -1;
  SimpleGasTurbineABG.subsystems.j_s.connections = [2 ];

# Component comp
  SimpleGasTurbineABG.subsystems.comp.type = "Pump";
  SimpleGasTurbineABG.subsystems.comp.cr = "none";
  SimpleGasTurbineABG.subsystems.comp.arg = "c_v;density,ideal_gas,r;alpha;effort,k";
  SimpleGasTurbineABG.subsystems.comp.repetitions = 1;
  SimpleGasTurbineABG.subsystems.comp.status = -1;
  SimpleGasTurbineABG.subsystems.comp.connections = [16 -14 1 12 -10 ];

# Component turb
  SimpleGasTurbineABG.subsystems.turb.type = "Pump";
  SimpleGasTurbineABG.subsystems.turb.cr = "none";
  SimpleGasTurbineABG.subsystems.turb.arg = "c_v;density,ideal_gas,r;alpha;effort,k";
  SimpleGasTurbineABG.subsystems.turb.repetitions = 1;
  SimpleGasTurbineABG.subsystems.turb.status = -1;
  SimpleGasTurbineABG.subsystems.turb.connections = [15 -17 -6 11 -13 ];

# Component Work
  SimpleGasTurbineABG.subsystems.Work.type = "SS";
  SimpleGasTurbineABG.subsystems.Work.cr = "SS";
  SimpleGasTurbineABG.subsystems.Work.arg = "0,external";
  SimpleGasTurbineABG.subsystems.Work.repetitions = 1;
  SimpleGasTurbineABG.subsystems.Work.status = -1;
  SimpleGasTurbineABG.subsystems.Work.connections = [4 ];

# Component Heat
  SimpleGasTurbineABG.subsystems.Heat.type = "SS";
  SimpleGasTurbineABG.subsystems.Heat.cr = "SS";
  SimpleGasTurbineABG.subsystems.Heat.arg = "0,external";
  SimpleGasTurbineABG.subsystems.Heat.repetitions = 1;
  SimpleGasTurbineABG.subsystems.Heat.status = -1;
  SimpleGasTurbineABG.subsystems.Heat.connections = [9 ];

# Component Speed
  SimpleGasTurbineABG.subsystems.Speed.type = "SS";
  SimpleGasTurbineABG.subsystems.Speed.cr = "SS";
  SimpleGasTurbineABG.subsystems.Speed.arg = "0,external";
  SimpleGasTurbineABG.subsystems.Speed.repetitions = 1;
  SimpleGasTurbineABG.subsystems.Speed.status = -1;
  SimpleGasTurbineABG.subsystems.Speed.connections = [5 ];

# Component T3
  SimpleGasTurbineABG.subsystems.T3.type = "SS";
  SimpleGasTurbineABG.subsystems.T3.cr = "SS";
  SimpleGasTurbineABG.subsystems.T3.arg = "external,external";
  SimpleGasTurbineABG.subsystems.T3.repetitions = 1;
  SimpleGasTurbineABG.subsystems.T3.status = -1;
  SimpleGasTurbineABG.subsystems.T3.connections = [-8 ];

# Component in
  SimpleGasTurbineABG.subsystems.in.type = "In";
  SimpleGasTurbineABG.subsystems.in.cr = "";
  SimpleGasTurbineABG.subsystems.in.arg = "";
  SimpleGasTurbineABG.subsystems.in.repetitions = 1;
  SimpleGasTurbineABG.subsystems.in.status = -1;
  SimpleGasTurbineABG.subsystems.in.connections = [-16 -12 ];

# Component out
  SimpleGasTurbineABG.subsystems.out.type = "Out";
  SimpleGasTurbineABG.subsystems.out.cr = "";
  SimpleGasTurbineABG.subsystems.out.arg = "";
  SimpleGasTurbineABG.subsystems.out.repetitions = 1;
  SimpleGasTurbineABG.subsystems.out.status = -1;
  SimpleGasTurbineABG.subsystems.out.connections = [17 13 ];

# Component mtt1
  SimpleGasTurbineABG.subsystems.mtt1.type = "1";
  SimpleGasTurbineABG.subsystems.mtt1.cr = "";
  SimpleGasTurbineABG.subsystems.mtt1.arg = "";
  SimpleGasTurbineABG.subsystems.mtt1.repetitions = 1;
  SimpleGasTurbineABG.subsystems.mtt1.status = -1;
  SimpleGasTurbineABG.subsystems.mtt1.connections = [-1 -2 -3 -5 6 ];

# Component mtt2
  SimpleGasTurbineABG.subsystems.mtt2.type = "Load";
  SimpleGasTurbineABG.subsystems.mtt2.cr = "";
  SimpleGasTurbineABG.subsystems.mtt2.arg = "";
  SimpleGasTurbineABG.subsystems.mtt2.repetitions = 1;
  SimpleGasTurbineABG.subsystems.mtt2.status = -1;
  SimpleGasTurbineABG.subsystems.mtt2.connections = [3 -4 ];

# Component mtt3
  SimpleGasTurbineABG.subsystems.mtt3.type = "PS";
  SimpleGasTurbineABG.subsystems.mtt3.cr = "";
  SimpleGasTurbineABG.subsystems.mtt3.arg = "";
  SimpleGasTurbineABG.subsystems.mtt3.repetitions = 1;
  SimpleGasTurbineABG.subsystems.mtt3.status = -1;
  SimpleGasTurbineABG.subsystems.mtt3.connections = [8 -7 -9 ];

# Ordered list of subsystem names
  SimpleGasTurbineABG.subsystemlist(1,:) = "c1   ";
  SimpleGasTurbineABG.subsystemlist(2,:) = "j_s  ";
  SimpleGasTurbineABG.subsystemlist(3,:) = "comp ";
  SimpleGasTurbineABG.subsystemlist(4,:) = "turb ";
  SimpleGasTurbineABG.subsystemlist(5,:) = "Work ";
  SimpleGasTurbineABG.subsystemlist(6,:) = "Heat ";
  SimpleGasTurbineABG.subsystemlist(7,:) = "Speed";
  SimpleGasTurbineABG.subsystemlist(8,:) = "T3   ";
  SimpleGasTurbineABG.subsystemlist(9,:) = "in   ";
  SimpleGasTurbineABG.subsystemlist(10,:) = "out  ";
  SimpleGasTurbineABG.subsystemlist(11,:) = "mtt1 ";
  SimpleGasTurbineABG.subsystemlist(12,:) = "mtt2 ";
  SimpleGasTurbineABG.subsystemlist(13,:) = "mtt3 ";

# Bonds 
  SimpleGasTurbineABG.bonds = [
      0 0 
      1 1 
      0 0 
      -1 -1 
      -1 -1 
      0 0 
      0 0 
      1 1 
      -1 -1 
      0 0 
      0 0 
      0 0 
      0 0 
      0 0 
      0 0 
      0 0 
      0 0 
      ];

# Aliases 
# A double underscore __ represents a comma 
# Explicit variable declarations
#VAR t_2
#VAR t_3
#VAR t_4
#VAR p_2
#VAR p_3
#VAR p_4
#VAR mdot
#VAR gamma_0
#VAR q_0
#VAR w_0
#VAR omega_0
#VAR r_p
#VAR c_p
#VAR mom_0
endfunction

% -*-latex-*- used to set EMACS into LaTeX-mode
% Verbal description for system SimpleGasTurbineABG (SimpleGasTurbineABG_desc.tex)
% Generated by MTT on Tue Jan 13 18:01:55 GMT 1998.

% %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
% %% Version control history
% %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
% %% $Id$
% %% $Log$
% %% Revision 1.1  1998/05/18 15:45:50  peterg
% %% Initial revision
% %%
% %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%

   The acausal bond graph of system \textbf{SimpleGasTurbineABG} is
   displayed in Figure \Ref{SimpleGasTurbineABG_abg} and its label
   file is listed in Section \Ref{sec:SimpleGasTurbineABG_lbl}.
   The subsystems are listed in Section \Ref{sec:SimpleGasTurbineABG_sub}.
   
   \textbf{SimpleGasTurbineABG} can be regarded as an single-spool gas
   turbine (producing shaft power) with an ideal-gas working fluid. It
   corresponds to the simple Joule Cycle as described in Chapter 12 of
   Rogers and Mayhew and in Chapter 2 of Cohen, Rogers and
   Saravanamutto. However, unlike those examples, the system is
   written with dynamics in mind.
   
   The system is described using an energy Bond Graph- this ensures
   that the first law is observed. In particular transformers are used
   to explicitly convert between energy covariables. Although this is
   a simple model, I believe that it provides the basis for building
   complex thermodynamic systems involving gas power cycles.


There are five main components:
\begin{enumerate}
\item p1 -- a \textbf{Pump} component representing the compressor
  stage. This converts shaft work to energy flow in the working fluid.
\item c1 -- a \textbf{Comb} component representing the combustion
  chamber. This converts the heat obtained by burning fuel to energy
  flow in the working fluid.
\item t1 -- a \textbf{Turb} component representing the turbine
  component. This converts the energy flow in the working fluid to
  shaft work
\item j\_s -- an \textbf{I} component representing the combined inertia
  of the shaft and compressor and turbine rotors.
\item a \textbf{Load} component to absorb the shaft power.
\end{enumerate}
The components \textbf{In} and \textbf{Out} provide the inlet and
outlet conditions.

Both \textbf{Pump} and \textbf{Turb} are implemented with the
\emph{polytropic} constitutive relationship with index $n$. When
$n=\gamma=\frac{c_p}{c_v}$ this corresponds to isentropic compression
and expansion and thus the \textbf{SimpleGasTurbineABG} achieves its
cycle efficiency. However, other values of $n$ can be used to account
for isentropic efficiency of less than unity.

To obtain a very simple dynamic model (and to avoid the need for an
accurate combustion chamber model) there are no dynamics associated
with the combustion chamber, but rahter it is assumed that the
corresponding temperature is imposed on the component (that is $T_3$
is the system input) the corresponding heat flow is then an output.

Both heat input and work output are measured using the \textbf{PS}
(power sensor) component, that for work output is embedded in the
\textbf{Load} component. These can be monitored to give the efficiency
of the \textbf{SimpleGasTurbineABG}.

A symbolic steady-state for the model was computed -- see Section
\ref{sec:SimpleGasTurbineABG_ss.tex}. In particular, the load
resistance was chosen to absorb all the generated work at the steady
state and the shaft inertia was chosen to give a unit time constant
for the linearised system. The mass flow and shaft speeds were taken
as unity.

For the purposed of simulation, the numerical values given in Examples
12.1 of Chapter 12 of Rogers and Mayhew, except that the isentropic
efficiencies are 100\% ($n=\gamma$) -- see Section
\ref{sec:SimpleGasTurbineABG_numpar.tex}.

Simulations were performed starting at the steady state and increasing
the combustion chamber temperature by 10\% at $t=1$ and reducing by
10\% at $t=5$. Graphs of the various outputs are plotted:
\begin{itemize}
\item Figure
  \Ref{fig:SimpleGasTurbineABG_odeso.ps-SimpleGasTurbineABG-p1-T,SimpleGasTurbineABG-c1-T,SimpleGasTurbineABG-t1-T}
  -- the temperatures at the output of the
  \begin{itemize}
  \item compressor,
  \item combustion chamber and
  \item turbine
  \end{itemize}
\item Figure
  \Ref{fig:SimpleGasTurbineABG_odeso.ps-SimpleGasTurbineABG-Heat,SimpleGasTurbineABG-Work}
  -- the heat input and work output
\item Figure
  \Ref{fig:SimpleGasTurbineABG_odeso.ps-SimpleGasTurbineABG-Speed} -- the shaft speed and
\item Figure
  \Ref{fig:SimpleGasTurbineABG_odeso.ps-SimpleGasTurbineABG-p1-P,SimpleGasTurbineABG-c1-P,SimpleGasTurbineABG-t1-P}
  -- the pressure at the output of the
  \begin{itemize}
  \item compressor,
  \item combustion chamber and
  \item turbine
  \end{itemize}
\end{itemize}

This model can be modified extended in various ways to yield related
dynamic systems. For example:
\begin{itemize}
\item an air cooler is obtained by changing the direction of heat and
  work flows
\item additional \textbf{Turb} and \textbf{Comb} components add reheat
  to the cycle
\item an isentropic nozzle can be added and the work output removed
  to give a jet engine.
\end{itemize}


%%% Local Variables: 
%%% mode: latex
%%% TeX-master: t
%%% End: 

# Numerical parameter file (SimpleGasTurbineABG_input.txt)
# Generated by MTT at Tue Mar 31 12:38:39 BST 1998

# %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
# %% Version control history
# %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
# %% $Id$
# %% $Log$
# %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%

t_3 = 1000;

# Set the inputs
u(1) =	 t_3 + 0.1*t_3*(t>1) -  0.2*t_3*(t>5); # SimpleGasTurbineABG (T3)

# Numerical parameter file (SimpleGasTurbine_numpar.txt)
# Generated by MTT at Tue Mar 31 12:15:00 BST 1998

# %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
# %% Version control history
# %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
# %% $Id$
# %% $Log$
# %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%

#Dummies
 alpha = 1;
 c_v = 1;
 density = 1;
 ideal_gas = 1;
 j_s = 1;
 k = 1;
 k_p = 1;
 m = 1;
 m_c = 1;
 p_1 = 1;
 r = 1;
 r_l = 1;
 t_1 = 1;
 v = 1;
 v_c = 1;


# Parameters
c_p = 	1005.0;
c_v = 	718.0; 
gamma_0 =  c_p/c_v;
alpha = (gamma_0-1)/gamma_0;
k = 	1.0;
p_1 = 	1e5; # 1 bar
p_4 = 	p_1; 
r = 	c_p-c_v;
t_1 = 	288.0; # In
v_c = 	1.0;

%Set the CC pressure and temperature
t_3 = 1000.0;
r_p = 6.0;
p_3 = r_p*p_1;

%Find stored mass to give combustion chamber pressure p_3 (at
% temperature t_3
m_c = (p_3*v_c)/(t_3*r);

%Equate pressures
p_4 = p_1;
p_2 = p_3;

%Compute ss temperatures (isentropic)
t_2 = t_1*(p_2/p_1)^alpha;
t_4 = t_3*(p_4/p_3)^alpha;

%Find the steady-state work output
w_0 = c_p*(t_3-t_4) - c_p*(t_2-t_1);

%Unit mass flow
mdot = 1;

%Corresponding shaft speed
omega_0 = mdot/k;

%Compute the corresponding load resistance (to absorb that work)
r_l = w_0/(omega_0)^2;

%Compute shaft inertia to give unit time constant (j_s*r_l)
j_s = r_l;

%Find angular momentum to give shaft speed omega_0
mom_0 =  omega_0*j_s;

# Outline report file for system SimpleGasTurbineABG (SimpleGasTurbineABG_rep.txt)

% %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
% %% Version control history
% %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
% %% $Id$
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%mtt -abg -o -ss SimpleGasTurbineABG abg tex
mtt -abg -o -ss SimpleGasTurbineABG struc tex
mtt -abg -o -ss SimpleGasTurbineABG sympar tex
mtt -abg -o -ss SimpleGasTurbineABG ode tex

mtt -abg -o -ss SimpleGasTurbineABG sspar r
mtt -abg -o -ss SimpleGasTurbineABG ss tex
mtt -abg -o -ss SimpleGasTurbineABG sm tex


mtt -abg -o -ss SimpleGasTurbineABG numpar tex
mtt -abg -o -ss SimpleGasTurbineABG input tex
mtt -abg -o -ss SimpleGasTurbineABG state tex
mtt -abg -o -ss SimpleGasTurbineABG simpar tex
mtt -abg -o -ss -c SimpleGasTurbineABG odeso ps 'SimpleGasTurbineABG_p1_T,SimpleGasTurbineABG_c1_T,SimpleGasTurbineABG_t1_T'
mtt -abg -o -ss -c SimpleGasTurbineABG odeso ps 'SimpleGasTurbineABG_Heat,SimpleGasTurbineABG_Work'
mtt -abg -o -ss -c SimpleGasTurbineABG odeso ps 'SimpleGasTurbineABG_Speed'
mtt -abg -o -ss -c SimpleGasTurbineABG odeso ps 'SimpleGasTurbineABG_p1_P,SimpleGasTurbineABG_c1_P,SimpleGasTurbineABG_t1_P'

%% Reduce commands to simplify output for system SimpleGasTurbineABG (SimpleGasTurbineABG_simp.r)

% %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
% %% Version control history
% %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
% %% $Id$
% %% $Log$
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LET c_v = c_p - r;
END;

% Steady-state parameter file (SimpleGasTurbineABG_sspar.r)
% Generated by MTT at Thu Mar 26 16:28:59 GMT 1998

% %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
% % Version control history
% %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
% % $Id$
% % $Log$
% %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%

%Find stored mass to give combustion chamber pressure p_3 (at
% temperature t_3
m_c := (p_3*v_c)/(t_3*r);

%Equate pressures
p_4 := p_1;
p_2 := p_3;

%Compute ss temperatures (isentropic)
t_2 := t_1*(p_2/p_1)^alpha;
t_4 := t_3*(p_4/p_3)^alpha;

%Find the steady-state work output
w_0 := c_p*(t_3-t_4) - c_p*(t_2-t_1);

%Compute the corresponding load resistance (to absorb that work)
r_l := w_0/(omega_0)^2;

%Unit mass flow
mdot := 1;

%Corresponding shaft speed
omega_0 := mdot/k;

%Compute shaft inertia to give unit time constant (j_s*r_l)
j_s := r_l;

%Find angular momentum to give shaft speed omega_0
mom_0 :=  omega_0*j_s;


% Steady-state states
MTTX1 := 	mom_0;

% Steady-state inputs - combustion temperature
MTTU1 := 	t_3; % SimpleGasTurbineABG (T3)

;;END;

# Numerical parameter file (SimpleGasTurbineABG_state.txt)
# Generated by MTT at Tue Mar 31 12:37:17 BST 1998

# %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
# %% Version control history
# %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
# %% $Id$
# %% $Log$
# %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%

SimpleGasTurbineABG_numpar;

# Set the states
x(1) =	 j_s/k ; # SimpleGasTurbineABG (j_s)

function [hPipe] =  hPipe_abg
# This function is the acausal bond graph representation of hPipe
# Generated by MTT on Thu Mar 16 10:33:07 2000
# The file is in Octave format

# Subsystems and Ports

# Port Heat
  hPipe.ports.Heat.type = "SS";
  hPipe.ports.Heat.cr = "SS";
  hPipe.ports.Heat.arg = "external,external";
  hPipe.ports.Heat.repetitions = 1;
  hPipe.ports.Heat.status = -1;
  hPipe.ports.Heat.connections = [-3 ];

# Port Hydraulic_in
  hPipe.ports.Hydraulic_in.type = "SS";
  hPipe.ports.Hydraulic_in.cr = "SS";
  hPipe.ports.Hydraulic_in.arg = "external,external";
  hPipe.ports.Hydraulic_in.repetitions = 1;
  hPipe.ports.Hydraulic_in.status = -1;
  hPipe.ports.Hydraulic_in.connections = [-5 ];

# Port Hydraulic_out
  hPipe.ports.Hydraulic_out.type = "SS";
  hPipe.ports.Hydraulic_out.cr = "SS";
  hPipe.ports.Hydraulic_out.arg = "external,external";
  hPipe.ports.Hydraulic_out.repetitions = 1;
  hPipe.ports.Hydraulic_out.status = -1;
  hPipe.ports.Hydraulic_out.connections = [6 ];

# Port Thermal_in
  hPipe.ports.Thermal_in.type = "SS";
  hPipe.ports.Thermal_in.cr = "SS";
  hPipe.ports.Thermal_in.arg = "external,external";
  hPipe.ports.Thermal_in.repetitions = 1;
  hPipe.ports.Thermal_in.status = -1;
  hPipe.ports.Thermal_in.connections = [-2 ];

# Port Thermal_out
  hPipe.ports.Thermal_out.type = "SS";
  hPipe.ports.Thermal_out.cr = "SS";
  hPipe.ports.Thermal_out.arg = "external,external";
  hPipe.ports.Thermal_out.repetitions = 1;
  hPipe.ports.Thermal_out.status = -1;
  hPipe.ports.Thermal_out.connections = [7 ];

# Component P2T
  hPipe.subsystems.P2T.type = "TF";
  hPipe.subsystems.P2T.cr = "lin";
  hPipe.subsystems.P2T.arg = "flow,r*m/v";
  hPipe.subsystems.P2T.repetitions = 1;
  hPipe.subsystems.P2T.status = -1;
  hPipe.subsystems.P2T.connections = [5 -1 ];

# Component T2P
  hPipe.subsystems.T2P.type = "TF";
  hPipe.subsystems.T2P.cr = "lin";
  hPipe.subsystems.T2P.arg = "effort,r*m/v";
  hPipe.subsystems.T2P.repetitions = 1;
  hPipe.subsystems.T2P.status = -1;
  hPipe.subsystems.T2P.connections = [4 -6 ];

# Component mtt1
  hPipe.subsystems.mtt1.type = "0";
  hPipe.subsystems.mtt1.cr = "";
  hPipe.subsystems.mtt1.arg = "";
  hPipe.subsystems.mtt1.repetitions = 1;
  hPipe.subsystems.mtt1.status = -1;
  hPipe.subsystems.mtt1.connections = [1 2 3 -4 -7 ];

# Ordered list of Port names
  hPipe.portlist(1,:) = "Heat         ";
  hPipe.portlist(2,:) = "Hydraulic_in ";
  hPipe.portlist(3,:) = "Hydraulic_out";
  hPipe.portlist(4,:) = "Thermal_in   ";
  hPipe.portlist(5,:) = "Thermal_out  ";

# Ordered list of subsystem names
  hPipe.subsystemlist(1,:) = "P2T ";
  hPipe.subsystemlist(2,:) = "T2P ";
  hPipe.subsystemlist(3,:) = "mtt1";

# Bonds 
  hPipe.bonds = [
      0 0 
      0 0 
      1 1 
      0 0 
      0 0 
      0 0 
      0 0 
      ];

# Aliases 
# A double underscore __ represents a comma 
hPipe.alias.out = "Thermal_out,Hydraulic_out";
hPipe.alias.Hy_out = "Hydraulic_out";
hPipe.alias.Th_in = "Thermal_in";
hPipe.alias.r = "$3";
hPipe.alias.Th_out = "Thermal_out";
hPipe.alias.m = "$1";
hPipe.alias.v = "$2";
hPipe.alias.in = "Thermal_in,Hydraulic_in";
hPipe.alias.Hy_in = "Hydraulic_in";

function [wPipe] =  wPipe_abg
# This function is the acausal bond graph representation of wPipe
# Generated by MTT on Thu Mar 16 10:37:39 2000
# The file is in Octave format

# Subsystems and Ports

# Port Hydraulic_in
  wPipe.ports.Hydraulic_in.type = "SS";
  wPipe.ports.Hydraulic_in.cr = "SS";
  wPipe.ports.Hydraulic_in.arg = "external,external";
  wPipe.ports.Hydraulic_in.repetitions = 1;
  wPipe.ports.Hydraulic_in.status = -1;
  wPipe.ports.Hydraulic_in.connections = [-1 ];

# Port Hydraulic_out
  wPipe.ports.Hydraulic_out.type = "SS";
  wPipe.ports.Hydraulic_out.cr = "SS";
  wPipe.ports.Hydraulic_out.arg = "external,external";
  wPipe.ports.Hydraulic_out.repetitions = 1;
  wPipe.ports.Hydraulic_out.status = -1;
  wPipe.ports.Hydraulic_out.connections = [17 ];

# Port Shaft
  wPipe.ports.Shaft.type = "SS";
  wPipe.ports.Shaft.cr = "SS";
  wPipe.ports.Shaft.arg = "external,external";
  wPipe.ports.Shaft.repetitions = 1;
  wPipe.ports.Shaft.status = -1;
  wPipe.ports.Shaft.connections = [-20 ];

# Port Thermal_in
  wPipe.ports.Thermal_in.type = "SS";
  wPipe.ports.Thermal_in.cr = "SS";
  wPipe.ports.Thermal_in.arg = "external,external";
  wPipe.ports.Thermal_in.repetitions = 1;
  wPipe.ports.Thermal_in.status = -1;
  wPipe.ports.Thermal_in.connections = [-14 ];

# Port Thermal_out
  wPipe.ports.Thermal_out.type = "SS";
  wPipe.ports.Thermal_out.cr = "SS";
  wPipe.ports.Thermal_out.arg = "external,external";
  wPipe.ports.Thermal_out.repetitions = 1;
  wPipe.ports.Thermal_out.status = -1;
  wPipe.ports.Thermal_out.connections = [16 ];

# Component rho1
  wPipe.subsystems.rho1.type = "Density";
  wPipe.subsystems.rho1.cr = "none";
  wPipe.subsystems.rho1.arg = "density,ideal_gas,r";
  wPipe.subsystems.rho1.repetitions = 1;
  wPipe.subsystems.rho1.status = -1;
  wPipe.subsystems.rho1.connections = [4 3 -5 ];

# Component rho2
  wPipe.subsystems.rho2.type = "Density";
  wPipe.subsystems.rho2.cr = "none";
  wPipe.subsystems.rho2.arg = "density,ideal_gas,r";
  wPipe.subsystems.rho2.repetitions = 1;
  wPipe.subsystems.rho2.status = -1;
  wPipe.subsystems.rho2.connections = [12 11 -10 ];

# Component p2pv
  wPipe.subsystems.p2pv.type = "EMTF";
  wPipe.subsystems.p2pv.cr = "lin";
  wPipe.subsystems.p2pv.arg = "flow";
  wPipe.subsystems.p2pv.repetitions = 1;
  wPipe.subsystems.p2pv.status = -1;
  wPipe.subsystems.p2pv.connections = [2 -9 5 ];

# Component pv2p
  wPipe.subsystems.pv2p.type = "EMTF";
  wPipe.subsystems.pv2p.cr = "lin";
  wPipe.subsystems.pv2p.arg = "effort";
  wPipe.subsystems.pv2p.repetitions = 1;
  wPipe.subsystems.pv2p.status = -1;
  wPipe.subsystems.pv2p.connections = [7 -18 10 ];

# Component t2u
  wPipe.subsystems.t2u.type = "TF";
  wPipe.subsystems.t2u.cr = "lin";
  wPipe.subsystems.t2u.arg = "effort,c_v";
  wPipe.subsystems.t2u.repetitions = 1;
  wPipe.subsystems.t2u.status = -1;
  wPipe.subsystems.t2u.connections = [15 -6 ];

# Component u2t
  wPipe.subsystems.u2t.type = "TF";
  wPipe.subsystems.u2t.cr = "lin";
  wPipe.subsystems.u2t.arg = "flow,c_v";
  wPipe.subsystems.u2t.repetitions = 1;
  wPipe.subsystems.u2t.status = -1;
  wPipe.subsystems.u2t.connections = [8 -13 ];

# Component mtt1
  wPipe.subsystems.mtt1.type = "0";
  wPipe.subsystems.mtt1.cr = "";
  wPipe.subsystems.mtt1.arg = "";
  wPipe.subsystems.mtt1.repetitions = 1;
  wPipe.subsystems.mtt1.status = -1;
  wPipe.subsystems.mtt1.connections = [-3 14 -15 ];

# Component mtt2
  wPipe.subsystems.mtt2.type = "0";
  wPipe.subsystems.mtt2.cr = "";
  wPipe.subsystems.mtt2.arg = "";
  wPipe.subsystems.mtt2.repetitions = 1;
  wPipe.subsystems.mtt2.status = -1;
  wPipe.subsystems.mtt2.connections = [1 -2 -4 ];

# Component mtt3
  wPipe.subsystems.mtt3.type = "1";
  wPipe.subsystems.mtt3.cr = "";
  wPipe.subsystems.mtt3.arg = "";
  wPipe.subsystems.mtt3.repetitions = 1;
  wPipe.subsystems.mtt3.status = -1;
  wPipe.subsystems.mtt3.connections = [6 -7 -8 9 19 ];

# Component mtt4
  wPipe.subsystems.mtt4.type = "0";
  wPipe.subsystems.mtt4.cr = "";
  wPipe.subsystems.mtt4.arg = "";
  wPipe.subsystems.mtt4.repetitions = 1;
  wPipe.subsystems.mtt4.status = -1;
  wPipe.subsystems.mtt4.connections = [-11 13 -16 ];

# Component mtt5
  wPipe.subsystems.mtt5.type = "0";
  wPipe.subsystems.mtt5.cr = "";
  wPipe.subsystems.mtt5.arg = "";
  wPipe.subsystems.mtt5.repetitions = 1;
  wPipe.subsystems.mtt5.status = -1;
  wPipe.subsystems.mtt5.connections = [-12 -17 18 ];

# Component mtt6
  wPipe.subsystems.mtt6.type = "1";
  wPipe.subsystems.mtt6.cr = "";
  wPipe.subsystems.mtt6.arg = "";
  wPipe.subsystems.mtt6.repetitions = 1;
  wPipe.subsystems.mtt6.status = -1;
  wPipe.subsystems.mtt6.connections = [-19 20 ];

# Ordered list of Port names
  wPipe.portlist(1,:) = "Hydraulic_in ";
  wPipe.portlist(2,:) = "Hydraulic_out";
  wPipe.portlist(3,:) = "Shaft        ";
  wPipe.portlist(4,:) = "Thermal_in   ";
  wPipe.portlist(5,:) = "Thermal_out  ";

# Ordered list of subsystem names
  wPipe.subsystemlist(1,:) = "rho1";
  wPipe.subsystemlist(2,:) = "rho2";
  wPipe.subsystemlist(3,:) = "p2pv";
  wPipe.subsystemlist(4,:) = "pv2p";
  wPipe.subsystemlist(5,:) = "t2u ";
  wPipe.subsystemlist(6,:) = "u2t ";
  wPipe.subsystemlist(7,:) = "mtt1";
  wPipe.subsystemlist(8,:) = "mtt2";
  wPipe.subsystemlist(9,:) = "mtt3";
  wPipe.subsystemlist(10,:) = "mtt4";
  wPipe.subsystemlist(11,:) = "mtt5";
  wPipe.subsystemlist(12,:) = "mtt6";

# Bonds 
  wPipe.bonds = [
      0 0 
      0 0 
      0 0 
      0 0 
      0 0 
      0 0 
      0 0 
      0 0 
      0 0 
      0 0 
      0 0 
      0 0 
      0 0 
      0 0 
      0 0 
      0 0 
      0 0 
      0 0 
      0 0 
      -1 -1 
      ];

# Aliases 
# A double underscore __ represents a comma 
wPipe.alias.out = "Thermal_out,Hydraulic_out";
wPipe.alias.Hy_out = "Hydraulic_out";
wPipe.alias.c_v = "$1";
wPipe.alias.Th_in = "Thermal_in";
wPipe.alias.Th_out = "Thermal_out";
wPipe.alias.Work = "Shaft";
wPipe.alias.in = "Thermal_in,Hydraulic_in";
wPipe.alias.Hy_in = "Hydraulic_in";
wPipe.alias.density__ideal_gas__r = "$2";

function [rc] =  rc_abg
# This function is the acausal bond graph representation of rc
# Generated by MTT on Thu Mar 16 08:45:29 2000
# The file is in Octave format

# Subsystems and Ports

# Component c
  rc.subsystems.c.type = "C";
  rc.subsystems.c.cr = "lin";
  rc.subsystems.c.arg = "effort,c";
  rc.subsystems.c.repetitions = 1;
  rc.subsystems.c.status = -1;
  rc.subsystems.c.connections = [5 ];

# Component r
  rc.subsystems.r.type = "R";
  rc.subsystems.r.cr = "lin";
  rc.subsystems.r.arg = "flow,r";
  rc.subsystems.r.repetitions = 1;
  rc.subsystems.r.status = -1;
  rc.subsystems.r.connections = [4 ];

# Component e1
  rc.subsystems.e1.type = "SS";
  rc.subsystems.e1.cr = "SS";
  rc.subsystems.e1.arg = "external,internal";
  rc.subsystems.e1.repetitions = 1;
  rc.subsystems.e1.status = -1;
  rc.subsystems.e1.connections = [-1 ];

# Component e2
  rc.subsystems.e2.type = "SS";
  rc.subsystems.e2.cr = "SS";
  rc.subsystems.e2.arg = "external,0";
  rc.subsystems.e2.repetitions = 1;
  rc.subsystems.e2.status = -1;
  rc.subsystems.e2.connections = [3 ];

# Component mtt1
  rc.subsystems.mtt1.type = "1";
  rc.subsystems.mtt1.cr = "";
  rc.subsystems.mtt1.arg = "";
  rc.subsystems.mtt1.repetitions = 1;
  rc.subsystems.mtt1.status = -1;
  rc.subsystems.mtt1.connections = [1 -2 -4 ];

# Component mtt2
  rc.subsystems.mtt2.type = "0";
  rc.subsystems.mtt2.cr = "";
  rc.subsystems.mtt2.arg = "";
  rc.subsystems.mtt2.repetitions = 1;
  rc.subsystems.mtt2.status = -1;
  rc.subsystems.mtt2.connections = [2 -3 -5 ];

# Ordered list of subsystem names
  rc.subsystemlist(1,:) = "c   ";
  rc.subsystemlist(2,:) = "r   ";
  rc.subsystemlist(3,:) = "e1  ";
  rc.subsystemlist(4,:) = "e2  ";
  rc.subsystemlist(5,:) = "mtt1";
  rc.subsystemlist(6,:) = "mtt2";

# Bonds 
  rc.bonds = [
      1 1 
      0 0 
      1 1 
      0 0 
      0 0 
      ];

# Aliases 
# A double underscore __ represents a comma 
rc.alias.r = "$2";
rc.alias.c = "$1";

% %% Outline report file for system rcABG (rcABG_rep.txt)
mtt rcABG struc tex
mtt rcABG ode tex
mtt rcABG sm tex
mtt rcABG tf tex
mtt rcABG sro ps
mtt rcABG lmfr ps
mtt rcABG nyfr ps

mtt rcABG numpar txt
mtt rcABG input txt
mtt -c rcABG odeso ps
mtt rcABG rep txt

#FIG 3.2
Portrait
Center
Metric
A4      
100.00
Single
-2
1200 2
6 4680 630 6570 1620
2 1 0 2 1 7 1 0 -1 0.000 0 0 -1 0 0 2
	 4725 1215 5175 1215
2 1 0 2 1 7 1 0 -1 0.000 0 0 -1 0 0 2
	 4725 1080 5175 1080
2 1 0 2 1 7 1 0 -1 0.000 0 0 -1 0 0 2
	 4950 675 4950 1080
2 1 0 2 1 7 1 0 -1 0.000 0 0 -1 0 0 2
	 4950 1215 4950 1575
2 1 0 2 1 7 1 0 -1 0.000 0 0 -1 1 0 2
	1 1 2.00 120.00 240.00
	 6075 1530 6075 765
4 0 1 1 0 0 20 0.0000 4 180 165 5355 1215 c\001
4 0 1 1 0 0 20 0.0000 4 180 165 6300 1170 e\001
4 0 1 1 0 0 20 0.0000 4 255 180 6390 1305 2\001
-6
1 3 0 2 1 7 1 0 -1 0.000 1 0.0000 1800 1125 162 162 1800 1125 1890 1260
2 1 0 2 -1 7 0 0 -1 0.000 0 0 -1 0 0 3
	 1802 4277 2702 4277 2477 4502
2 1 0 2 -1 7 0 0 -1 0.000 0 0 -1 0 0 3
	 3152 4277 4052 4277 3827 4502
2 1 0 2 -1 7 0 0 -1 0.000 0 0 -1 0 0 3
	 4502 4277 5402 4277 5177 4502
2 1 0 2 -1 7 0 0 -1 0.000 0 0 -1 0 0 3
	 2926 4051 2926 3151 3151 3376
2 1 0 2 -1 7 0 0 -1 0.000 0 0 -1 0 0 3
	 4276 4051 4276 3151 4501 3376
2 1 0 2 -1 7 0 0 -1 0.000 0 0 -1 0 0 2
	 2701 4276 2701 4501
2 1 0 2 -1 7 0 0 -1 0.000 0 0 -1 0 0 2
	 5401 4051 5401 4276
2 1 0 2 -1 7 0 0 -1 0.000 0 0 -1 0 0 2
	 5401 4276 5401 4501
2 1 0 2 -1 7 0 0 -1 0.000 0 0 -1 0 0 2
	 2701 4051 2701 4276
2 2 0 2 1 7 1 0 -1 0.000 0 0 -1 0 0 5
	 2475 585 3375 585 3375 765 2475 765 2475 585
2 1 0 2 1 7 1 0 -1 0.000 0 0 -1 0 0 2
	 1800 675 2475 675
2 1 0 2 1 7 1 0 -1 0.000 0 0 -1 0 0 2
	 1800 945 1800 675
2 1 0 2 1 7 1 0 -1 0.000 0 0 -1 0 0 2
	 1800 1575 1800 1260
2 1 0 2 -1 7 0 0 -1 0.000 0 0 -1 0 0 3
	 2925 4500 2925 5400 3150 5175
2 4 0 2 31 7 1 0 -1 0.000 0 0 7 0 0 5
	 6750 6075 6750 225 675 225 675 6075 6750 6075
2 2 0 2 1 7 1 0 -1 0.000 0 0 -1 0 0 5
	 3600 585 4500 585 4500 765 3600 765 3600 585
2 1 0 2 1 7 101 0 -1 0.000 0 0 -1 0 0 2
	 3375 675 3600 675
2 1 0 2 1 7 101 0 -1 0.000 0 0 -1 0 0 2
	 4500 675 5850 675
2 1 0 2 1 7 101 0 -1 0.000 0 0 -1 0 0 2
	 1755 1575 5850 1575
2 1 0 2 4 7 100 0 -1 0.000 0 0 -1 0 0 2
	 1935 5040 2160 5265
2 1 0 2 4 7 0 0 -1 0.000 0 0 -1 0 0 3
	 2070 5130 2706 4494 2706 4812
4 1 -1 0 0 0 20 0.0000 4 255 180 2927 4367 1\001
4 1 -1 0 0 0 20 0.0000 4 255 180 4277 4367 0\001
4 1 -1 0 0 0 20 0.0000 4 255 825 5987 4367 SS:e2\001
4 1 -1 0 0 0 20 0.0000 4 330 825 2926 2926 R:r_1\001
4 1 -1 0 0 0 20 0.0000 4 255 495 4276 2926 C:c\001
4 1 -1 0 0 0 20 0.0000 4 255 825 1395 4365 SS:e1\001
4 0 1 1 0 0 20 0.0000 4 330 495 2880 450 r_1\001
4 0 1 1 0 0 20 0.0000 4 180 165 1260 1170 e\001
4 0 1 1 0 0 20 0.0000 4 255 180 1350 1305 1\001
4 1 1 1 0 0 20 0.0000 4 255 1545 3600 2025 Schematic\001
4 1 1 1 0 0 20 0.0000 4 330 1725 4860 4860 Bond graph\001
4 1 -1 0 0 0 20 0.0000 4 330 825 3015 5715 R:r_2\001
4 0 1 1 0 0 20 0.0000 4 330 495 3870 450 r_2\001
4 1 -1 0 0 0 20 0.0000 4 330 1110 1755 5535 SS:loop\001

% Verbal description for system aRC (aRC_desc.tex)
% Generated by MTT on Sun Aug 24 11:03:55 BST 1997.

% %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
% %% Version control history
% %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
% %% $Id$
% %% $Log$
% %% Revision 1.1  1997/08/24 10:27:18  peterg
% %% Initial revision
% %%
% %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%

   The acausal bond graph of system \textbf{aRC} is
   displayed in Figure \Ref{aRC_abg} and its label
   file is listed in Section \Ref{sec:aRC_lbl}.
   The subsystems are listed in Section \Ref{sec:aRC_sub}.

The system \textbf{aRC} is the simple electrical aRC ciaRCuit shown in
Figure \Ref{aRC_abg}. It can be regarded as a single-input
single-output system with input $e_1$ and output $e_2$.

The two resistors ($r_1$ and $r_2$) are in series; this give an
undercausal system with a corresponding algebraic loop. The loop is
broken by adding the {\bf SS} component ``loop'' to localise the
algabraic equation to choosinf the corresponding flow such that the
corresponding effort is zero. This algebraic equation appears in
Section \Ref{sec:aRC_dae.tex}.

This loop is algbraicly solved to give the ordinary differential
equation of Section \Ref{sec:aRC_ode.tex} and the transfer function of
Section \Ref{sec:aRC_tf.tex}.

%SUMMARY aRC: Simple RC circuit example with algebraic loop

%% Label file for system aRC (aRC_lbl.txt)

% %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
% %% Version control history
% %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
% %% $Id$
% %% $Log$
% %% Revision 1.1  2000/05/20 16:03:15  peterg
% %% Initial revision
% %%
% %% Revision 1.1  1997/05/12  15:11:47  peterg
% %% Initial revision
% %%
% %% Revision 1.1  1997/04/18  13:27:54  peterg
% %% Initial revision
% %%
% %% Revision 1.1  1997/04/18  13:20:13  peterg
% %% Initial revision
% %% Revision 1.1  1996/09/10 11:37:14  peter
% %% Initial revision
% %%
% %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%

%% Each line should be of one of the following forms:
%	a comment (ie starting with %)
%	Component-name	CR_name	arg1,arg2,..argn
%	blank

% Source - effort source (e1) flow ignored
e1	SS external,internal

% Sensor - effort sensor (e2)	zero flow
e2	SS external,0

% R component - linear with resistance r (effort = r*flow)
r_1	lin	flow,r_1
r_2	lin	flow,r_2

% C component - linear with capacitance c (state = c*effort)
c	lin	effort,c

% Algebraic loop SS
loop	SS      zero,unknown

## -*-octave-*- Put Emacs into octave-mode
## Outline report file for system aRC (aRC_rep.txt)
## Generated by MTT on" Fri Oct 15 14:56:13 EST 1999.

###############################################################
## Version control history
###############################################################
## $Id$
## $Log$
###############################################################

mtt aRC abg tex			# The system description
mtt aRC cbg ps 		        # The causal bond graph
## Uncomment the following lines or add others
mtt aRC struc tex	        # The system structure
mtt aRC dae tex			# The system dae
mtt -A aRC ode tex	        # The system ode 
## mtt aRC sspar tex		# Steady-state parameters
## mtt aRC ss tex 		# Steady state
## mtt aRC dm tex		# Descriptor matrices (of linearised system)
## mtt aRC sm tex		# State matrices (of linearised system)
## mtt -A aRC tf tex		# Transfer function (of linearised system)
## mtt aRC lmfr ps		# log modulus of frequency response (of linearised system)
## mtt aRC simpar tex		# Simulation parameters
## mtt aRC numpar tex		# Numerical simulation parameters
## mtt aRC input tex		# Simulation input
## mtt aRC odeso ps		# Simulation output

%% Reduce steady-state parameter file for aRC (aRC_sspar.r) cat /home/peter/mtt_new/mtt/trans/m/aRCs_header.txt
END;