📄 sfun_keyboard_input_v1_01.m
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function [sys,x0,str,ts] = sfun_keyboard_input_v1_01(t,x,u,flag,Ts)
%SFUNTMPL General M-file S-function template
% With M-file S-functions, you can define you own ordinary differential
% equations (ODEs), discrete system equations, and/or just about
% any type of algorithm to be used within a Simulink block diagram.
%
% The general form of an M-File S-function syntax is:
% [SYS,X0,STR,TS] = SFUNC(T,X,U,FLAG,P1,...,Pn)
%
% What is returned by SFUNC at a given point in time, T, depends on the
% value of the FLAG, the current state vector, X, and the current
% input vector, U.
%
% FLAG RESULT DESCRIPTION
% ----- ------ --------------------------------------------
% 0 [SIZES,X0,STR,TS] Initialization, return system sizes in SYS,
% initial state in X0, state ordering strings
% in STR, and sample times in TS.
% 1 DX Return continuous state derivatives in SYS.
% 2 DS Update discrete states SYS = X(n+1)
% 3 Y Return outputs in SYS.
% 4 TNEXT Return next time hit for variable step sample
% time in SYS.
% 5 Reserved for future (root finding).
% 9 [] Termination, perform any cleanup SYS=[].
%
%
% The state vectors, X and X0 consists of continuous states followed
% by discrete states.
%
% Optional parameters, P1,...,Pn can be provided to the S-function and
% used during any FLAG operation.
%
% When SFUNC is called with FLAG = 0, the following information
% should be returned:
%
% SYS(1) = Number of continuous states.
% SYS(2) = Number of discrete states.
% SYS(3) = Number of outputs.
% SYS(4) = Number of inputs.
% Any of the first four elements in SYS can be specified
% as -1 indicating that they are dynamically sized. The
% actual length for all other flags will be equal to the
% length of the input, U.
% SYS(5) = Reserved for root finding. Must be zero.
% SYS(6) = Direct feedthrough flag (1=yes, 0=no). The s-function
% has direct feedthrough if U is used during the FLAG=3
% call. Setting this to 0 is akin to making a promise that
% U will not be used during FLAG=3. If you break the promise
% then unpredictable results will occur.
% SYS(7) = Number of sample times. This is the number of rows in TS.
%
%
% X0 = Initial state conditions or [] if no states.
%
% STR = State ordering strings which is generally specified as [].
%
% TS = An m-by-2 matrix containing the sample time
% (period, offset) information. Where m = number of sample
% times. The ordering of the sample times must be:
%
% TS = [0 0, : Continuous sample time.
% 0 1, : Continuous, but fixed in minor step
% sample time.
% PERIOD OFFSET, : Discrete sample time where
% PERIOD > 0 & OFFSET < PERIOD.
% -2 0]; : Variable step discrete sample time
% where FLAG=4 is used to get time of
% next hit.
%
% There can be more than one sample time providing
% they are ordered such that they are monotonically
% increasing. Only the needed sample times should be
% specified in TS. When specifying than one
% sample time, you must check for sample hits explicitly by
% seeing if
% abs(round((T-OFFSET)/PERIOD) - (T-OFFSET)/PERIOD)
% is within a specified tolerance, generally 1e-8. This
% tolerance is dependent upon your model's sampling times
% and simulation time.
%
% You can also specify that the sample time of the S-function
% is inherited from the driving block. For functions which
% change during minor steps, this is done by
% specifying SYS(7) = 1 and TS = [-1 0]. For functions which
% are held during minor steps, this is done by specifying
% SYS(7) = 1 and TS = [-1 1].
% modified from sfuntmpl.m by
% Marc Compere
% CompereM@asme.org
% created : 17 June 2003
% modified: 20 June 2003
% Copyright 1990-2002 The MathWorks, Inc.
% $Revision: 1.18 $
%
% The following outlines the general structure of an S-function.
%
switch flag,
%%%%%%%%%%%%%%%%%%
% Initialization %
%%%%%%%%%%%%%%%%%%
case 0,
[sys,x0,str,ts]=mdlInitializeSizes(Ts);
%%%%%%%%%%%%%%%
% Derivatives %
%%%%%%%%%%%%%%%
case 1,
sys=mdlDerivatives(t,x,u);
%%%%%%%%%%
% Update %
%%%%%%%%%%
case 2,
sys=mdlUpdate(t,x,u);
%%%%%%%%%%%
% Outputs %
%%%%%%%%%%%
case 3,
sys=mdlOutputs(t,x,u);
%%%%%%%%%%%%%%%%%%%%%%%
% GetTimeOfNextVarHit %
%%%%%%%%%%%%%%%%%%%%%%%
case 4,
sys=mdlGetTimeOfNextVarHit(t,x,u);
%%%%%%%%%%%%%
% Terminate %
%%%%%%%%%%%%%
case 9,
sys=mdlTerminate(t,x,u);
%%%%%%%%%%%%%%%%%%%%
% Unexpected flags %
%%%%%%%%%%%%%%%%%%%%
otherwise
error(['Unhandled flag = ',num2str(flag)]);
end
% end sfuntmpl
%
%=============================================================================
% mdlInitializeSizes
% Return the sizes, initial conditions, and sample times for the S-function.
%=============================================================================
%
function [sys,x0,str,ts]=mdlInitializeSizes(Ts)
%
% call simsizes for a sizes structure, fill it in and convert it to a
% sizes array.
%
% Note that in this example, the values are hard coded. This is not a
% recommended practice as the characteristics of the block are typically
% defined by the S-function parameters.
%
sizes = simsizes;
sizes.NumContStates = 0;
sizes.NumDiscStates = 1;
sizes.NumOutputs = 1;
sizes.NumInputs = 0;
sizes.DirFeedthrough = 1;
sizes.NumSampleTimes = 1; % at least one sample time is needed
sys = simsizes(sizes);
%
% initialize the initial conditions
%
x0 = 43; % init with the ascii representation of a '+' character
%
% str is always an empty matrix
%
str = [];
%
% initialize the array of sample times
%
ts = [Ts 0]; % set Ts to some stepsize to avoid evaluating this S-fcn every time step
% -----------------------------------------------------------------
%
% Initialize Figure Window
%
handle.figure=findobj('type','figure','Tag','keyboard input figure');
if isempty(handle.figure)
% 'position' args -> [left, bottom, width, height]
handle.figure=figure('position',[100 100 400 200],...
'WindowStyle','Modal',...
'Color',get(0,'DefaultUicontrolBackgroundColor')); %,...
%'HandleVisibility','callback');
%handle.figure=figure('position',[800 620 400 300]);
%handle.figure=figure('position',[800 620 400 300],'WindowButtonDownFcn',@myCallback)
%handle.figure=figure('position',[800 620 400 300],'WindowButtonMoveFcn',@myCallback_move,'WindowButtonDownFcn',@myCallback_clickdown)
set(handle.figure,'Tag','keyboard input figure');
% Make the OFF button (position args->[left bottom width height])
handle.offbutton = uicontrol(handle.figure,...
'Style','pushbutton',...
'Units','characters',...
'Position',[5 5 46 2],...
'String','Disable exclusive figure-keyboard input',...
'Callback',{@turn_modal_off,handle});
% Make the ON button (position args->[left bottom width height])
handle.onbutton = uicontrol(handle.figure,...
'Style','pushbutton',...
'Units','characters',...
'Position',[5 1 46 2],...
'String','Re-enable exclusive figure-keyboard input',...
'Callback',{@turn_modal_on,handle});
else, % reset the figure to 'modal' to continue accepting keyboard input
set(handle.figure,'WindowStyle','Modal')
end
%handle.axis = axis;
%text(0.2,0.5,sprintf('Hit Ctrl-C to stop keyboard input\nexclusively through this figure'))
%
% Initialize Axes & line object (the point)
%
% steer_min = -pi; % (rad) max positive steering input signal
% steer_max = +pi; % (rad) max negative steering input signal
% throttle_min = -1.0; % (unitless) normalized max positive throttle signal
% throttle_max = +1.0; % (unitless) normalized max negative throttle signal
% axis_dims=[steer_min steer_max throttle_min throttle_max]; % [XMIN XMAX YMIN YMAX]
%set(handle.figure,'userdata',handle) % store handle structure in figure userdata space
% -----------------------------------------------------------------
% end mdlInitializeSizes
%
%=============================================================================
% mdlDerivatives
% Return the derivatives for the continuous states.
%=============================================================================
%
function sys=mdlDerivatives(t,x,u)
sys = [];
% end mdlDerivatives
%
%=============================================================================
% mdlUpdate
% Handle discrete state updates, sample time hits, and major time step
% requirements.
%=============================================================================
%
function sys=mdlUpdate(t,x,u)
handle.figure = findobj('type','figure','Tag','keyboard input figure'); % retrieve figure handle
%handle = get(handle.figure,'userdata');
current_char=get(handle.figure,'CurrentCharacter'); % a single character, like 'b'
% update the grahics object
%set(handle.point,'Xdata',[x(1) x(1)],'Ydata',[x(2) x(2)],'Zdata',[-1 +1]);
% conditionally update the (numeric) state
if ~strcmp(current_char,''), % if current_char is not blank, assign it to the state
sys = str2num(sprintf('%i',current_char));
else,
sys=0;
end
% reset 'CurrentCharacter' so if user lifts up from key, this is noticed
set(handle.figure,'CurrentCharacter','+') % the plus key is the only key that may be
% pressed, but when the user stops, is not noticed
% notes:
% - use sprintf() to convert string -> number contained in a string (or character) variable
% - use char() to convert floating point number -> ascii character
% - use str2num() to convert the string-number into a (double) floating point number
% - use str2num() with char() to convert a number-string into a char-string
% char(97) == char(str2num('97')) --> 'a'
% - use num2str() to convert a (double) number into the same number but contained
% in a string variable
% For example:
% tmp='a'; % assign a string
% tmp_num=sprintf('%i',tmp) % convert that string into a number contained in a string variable, tmp_num
% (tmp_num is the string containing the characters '97')
% tmp_char=char(str2num(tmp_num)) % convert that string variable back into a number, then into the original string
% end mdlUpdate
%
%=============================================================================
% mdlOutputs
% Return the block outputs.
%=============================================================================
%
function sys=mdlOutputs(t,x,u)
% output the current 2 states, the [x,y] graphics pair most recently updated
sys = x; % [x(1),x(2)] -> [abscissa, ordinate] -> [x,y]
% end mdlOutputs
%
%=============================================================================
% mdlGetTimeOfNextVarHit
% Return the time of the next hit for this block. Note that the result is
% absolute time. Note that this function is only used when you specify a
% variable discrete-time sample time [-2 0] in the sample time array in
% mdlInitializeSizes.
%=============================================================================
%
function sys=mdlGetTimeOfNextVarHit(t,x,u)
% unised unless ts=[-2 0] in mdlInitializesizes
sampleTime = Ts; % set the next hit to be Ts seconds later.
sys = t + sampleTime;
% end mdlGetTimeOfNextVarHit
%
%=============================================================================
% mdlTerminate
% Perform any end of simulation tasks.
%=============================================================================
%
function sys=mdlTerminate(t,x,u)
sys = [];
% end mdlTerminate
% Callback for turning Modal OFF
function turn_modal_off(obj,eventdata,handle)
%disp('turn_modal_off:')
%handle
set(handle.figure,'WindowStyle','Normal')
%end
% Callback for turning Modal ON
function turn_modal_on(obj,eventdata,handle)
%disp('turn_modal_on:')
%handle
set(handle.figure,'WindowStyle','Modal')
%end
% % Callback for 'WindowButtonMoveFcn' in figure
% function myCallback_move(obj,eventdata)
% str=sprintf('\tWindowButtonMoveFcn callback executing');disp(str)
% end
%
% % Callback for 'WindowButtonDownFcn' in figure
% function myCallback_clickdown(obj,eventdata)
% str=sprintf('\t\tWindowButtonDownFcn callback executing');disp(str)
% end
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