Файл: Проектирование реализации операций бизнес-процесса «Движение библиотечного фонда» (ДИАГРАММА ПОСЛЕДОВАТЕЛЬНОСТИ).pdf

end

if i == 4 && nogo == 0

h = errordlg('Point unreachable due to joint angle constraints.','JOINT ERROR');

waitfor(h);

nogo = 1;

noplot = 1;

break

end

end

end

end

%

%%

function pumaANI(theta1,theta2,theta3,theta4,theta5,theta6,n,trail)

% This function will animate the Puma 762 robot given joint angles.

% n is number of steps for the animation

% trail is 'y' or 'n' (n = anything else) for leaving a trail.

%

%disp('in animate');

a2 = 650; %D-H paramaters

a3 = 0;

d3 = 190;

d4 = 600;

% Err2 = 0;

%

ThetaOld = getappdata(0,'ThetaOld');

%

theta1old = ThetaOld(1);

theta2old = ThetaOld(2);

theta3old = ThetaOld(3);

theta4old = ThetaOld(4);

theta5old = ThetaOld(5);

theta6old = ThetaOld(6);

%

t1 = linspace(theta1old,theta1,n);

t2 = linspace(theta2old,theta2,n);

t3 = linspace(theta3old,theta3,n);% -180;

t4 = linspace(theta4old,theta4,n);

t5 = linspace(theta5old,theta5,n);

t6 = linspace(theta6old,theta6,n);

n = length(t1);

for i = 2:1:n

% Forward Kinematics

%

T_01 = tmat(0, 0, 0, t1(i));

T_12 = tmat(-90, 0, 0, t2(i));

T_23 = tmat(0, a2, d3, t3(i));

T_34 = tmat(-90, a3, d4, t4(i));

T_45 = tmat(90, 0, 0, t5(i));

T_56 = tmat(-90, 0, 0, t6(i));

%

% % T_67 = [ 1 0 0 0

% % 0 1 0 0

% % 0 0 1 188

% % 0 0 0 1];

%T_01 = T_01; % it is, but don't need to say so.

T_02 = T_01*T_12;

T_03 = T_02*T_23;

T_04 = T_03*T_34;

T_05 = T_04*T_45;

T_06 = T_05*T_56;

% T_07 = T_06*T_67;

%

s1 = getappdata(0,'Link1_data');

s2 = getappdata(0,'Link2_data');

s3 = getappdata(0,'Link3_data');

s4 = getappdata(0,'Link4_data');

s5 = getappdata(0,'Link5_data');

s6 = getappdata(0,'Link6_data');

s7 = getappdata(0,'Link7_data');

%A1 = getappdata(0,'Area_data');

Link1 = s1.V1;

Link2 = (T_01*s2.V2')';

Link3 = (T_02*s3.V3')';

Link4 = (T_03*s4.V4')';

Link5 = (T_04*s5.V5')';

Link6 = (T_05*s6.V6')';

Link7 = (T_06*s7.V7')';

% Tool = T_07;

% if sqrt(Tool(1,4)^2+Tool(2,4)^2)<514

% Err2 = 1;

% break

% end

%

handles = getappdata(0,'patch_h'); %

L1 = handles(1);

L2 = handles(2);

L3 = handles(3);

L4 = handles(4);

L5 = handles(5);

L6 = handles(6);

L7 = handles(7);

Tr = handles(9);

%

set(L1,'vertices',Link1(:,1:3),'facec', [0.717,0.116,0.123]);

set(L1, 'EdgeColor','none');

set(L2,'vertices',Link2(:,1:3),'facec', [0.216,1,.583]);

set(L2, 'EdgeColor','none');

set(L3,'vertices',Link3(:,1:3),'facec', [0.306,0.733,1]);

set(L3, 'EdgeColor','none');

set(L4,'vertices',Link4(:,1:3),'facec', [1,0.542,0.493]);

set(L4, 'EdgeColor','none');

set(L5,'vertices',Link5(:,1:3),'facec', [0.216,1,.583]);

set(L5, 'EdgeColor','none');

set(L6,'vertices',Link6(:,1:3),'facec', [1,1,0.255]);

set(L6, 'EdgeColor','none');

set(L7,'vertices',Link7(:,1:3),'facec', [0.306,0.733,1]);

set(L7, 'EdgeColor','none');

% store trail in appdata

if trail == 'y'

x_trail = getappdata(0,'xtrail');

y_trail = getappdata(0,'ytrail');

z_trail = getappdata(0,'ztrail');

%

xdata = [x_trail T_04(1,4)];

ydata = [y_trail T_04(2,4)];

zdata = [z_trail T_04(3,4)];

%

setappdata(0,'xtrail',xdata); % used for trail tracking.

setappdata(0,'ytrail',ydata); % used for trail tracking.

setappdata(0,'ztrail',zdata); % used for trail tracking.

%

set(Tr,'xdata',xdata,'ydata',ydata,'zdata',zdata);

end

drawnow

end

setappdata(0,'ThetaOld',[theta1,theta2,theta3,theta4,theta5,theta6]);

end

%%

%

%

%%

function InitHome

% Use forward kinematics to place the robot in a specified

% configuration.

% Figure setup data, create a new figure for the GUI

set(0,'Units','pixels')

dim = get(0,'ScreenSize');

fig_1 = figure('doublebuffer','on','Position',[0,35,dim(3)-200,dim(4)-110],...

'MenuBar','none','Name',' 3D Puma Robot Graphical Demo',...

---

'NumberTitle','off','CloseRequestFcn',@del_app);

hold on;

%light('Position',[-1 0 0]);

light % add a default light

daspect([1 1 1]) % Setting the aspect ratio

view(135,25)

xlabel('X'),ylabel('Y'),zlabel('Z');

title('WWU Robotics Lab PUMA 762');

axis([-1500 1500 -1500 1500 -1120 1500]);

plot3([-1500,1500],[-1500,-1500],[-1120,-1120],'k')

plot3([-1500,-1500],[-1500,1500],[-1120,-1120],'k')

plot3([-1500,-1500],[-1500,-1500],[-1120,1500],'k')

plot3([-1500,-1500],[1500,1500],[-1120,1500],'k')

plot3([-1500,1500],[-1500,-1500],[1500,1500],'k')

plot3([-1500,-1500],[-1500,1500],[1500,1500],'k')

s1 = getappdata(0,'Link1_data');

s2 = getappdata(0,'Link2_data');

s3 = getappdata(0,'Link3_data');

s4 = getappdata(0,'Link4_data');

s5 = getappdata(0,'Link5_data');

s6 = getappdata(0,'Link6_data');

s7 = getappdata(0,'Link7_data');

A1 = getappdata(0,'Area_data');

%

a2 = 650;

a3 = 0;

d3 = 190;

d4 = 600;

Px = 5000;

Py = 5000;

Pz = 5000;

%The 'home' position, for init.

t1 = 90;

t2 = -90;

t3 = -90;

t4 = 0;

t5 = 0;

t6 = 0;

% Forward Kinematics

T_01 = tmat(0, 0, 0, t1);

T_12 = tmat(-90, 0, 0, t2);

T_23 = tmat(0, a2, d3, t3);

T_34 = tmat(-90, a3, d4, t4);

T_45 = tmat(90, 0, 0, t5);

T_56 = tmat(-90, 0, 0, t6);

% Each link fram to base frame transformation

T_02 = T_01*T_12;

T_03 = T_02*T_23;

T_04 = T_03*T_34;

T_05 = T_04*T_45;

T_06 = T_05*T_56;

% Actual vertex data of robot links

Link1 = s1.V1;

Link2 = (T_01*s2.V2')';

Link3 = (T_02*s3.V3')';

Link4 = (T_03*s4.V4')';

Link5 = (T_04*s5.V5')';

Link6 = (T_05*s6.V6')';

Link7 = (T_06*s7.V7')';

% points are no fun to watch, make it look 3d.

L1 = patch('faces', s1.F1, 'vertices' ,Link1(:,1:3));

L2 = patch('faces', s2.F2, 'vertices' ,Link2(:,1:3));

L3 = patch('faces', s3.F3, 'vertices' ,Link3(:,1:3));

L4 = patch('faces', s4.F4, 'vertices' ,Link4(:,1:3));

L5 = patch('faces', s5.F5, 'vertices' ,Link5(:,1:3));

L6 = patch('faces', s6.F6, 'vertices' ,Link6(:,1:3));

L7 = patch('faces', s7.F7, 'vertices' ,Link7(:,1:3));

A1 = patch('faces', A1.Fa, 'vertices' ,A1.Va(:,1:3));

Tr = plot3(0,0,0,'b.'); % holder for trail paths

%

setappdata(0,'patch_h',[L1,L2,L3,L4,L5,L6,L7,A1,Tr])

%

setappdata(0,'xtrail',0); % used for trail tracking.

setappdata(0,'ytrail',0); % used for trail tracking.

setappdata(0,'ztrail',0); % used for trail tracking.

%

set(L1, 'facec', [0.717,0.116,0.123]);

set(L1, 'EdgeColor','none');

set(L2, 'facec', [0.216,1,.583]);

set(L2, 'EdgeColor','none');

set(L3, 'facec', [0.306,0.733,1]);

set(L3, 'EdgeColor','none');

set(L4, 'facec', [1,0.542,0.493]);

set(L4, 'EdgeColor','none');

set(L5, 'facec', [0.216,1,.583]);

set(L5, 'EdgeColor','none');

set(L6, 'facec', [1,1,0.255]);

set(L6, 'EdgeColor','none');

set(L7, 'facec', [0.306,0.733,1]);

set(L7, 'EdgeColor','none');

set(A1, 'facec', [.8,.8,.8],'FaceAlpha',.25);

set(A1, 'EdgeColor','none');

%

setappdata(0,'ThetaOld',[90,-90,-90,0,0,0]);

%

end

%%

function T = tmat(alpha, a, d, theta)

% tmat(alpha, a, d, theta) (T-Matrix used in Robotics)

% The homogeneous transformation called the "T-MATRIX"

% as used in the Kinematic Equations for robotic type

% systems (or equivalent).

%

% This is equation 3.6 in Craig's "Introduction to Robotics."

% alpha, a, d, theta are the Denavit-Hartenberg parameters.

%

% (NOTE: ALL ANGLES MUST BE IN DEGREES.)

%

alpha = alpha*pi/180; %Note: alpha is in radians.

theta = theta*pi/180; %Note: theta is in radians.

c = cos(theta);

s = sin(theta);

ca = cos(alpha);

sa = sin(alpha);

T = [c -s 0 a; s*ca c*ca -sa -sa*d; s*sa c*sa ca ca*d; 0 0 0 1];

end

%%

function del_app(varargin)

%This is the main figure window close function, to remove any

% app data that may be left due to using it for geometry.

%CloseRequestFcn

---

% here is the data to remove:

% Link1_data: [1x1 struct]

% Link2_data: [1x1 struct]

% Link3_data: [1x1 struct]

% Link4_data: [1x1 struct]

% Link5_data: [1x1 struct]

% Link6_data: [1x1 struct]

% Link7_data: [1x1 struct]

% Area_data: [1x1 struct]

% patch_h: [1x9 double]

% ThetaOld: [90 -182 -90 -106 80 106]

% xtrail: 0

% ytrail: 0

% ztrail: 0

% Now remove them.

rmappdata(0,'Link1_data');

rmappdata(0,'Link2_data');

rmappdata(0,'Link3_data');

rmappdata(0,'Link4_data');

rmappdata(0,'Link5_data');

rmappdata(0,'Link6_data');

rmappdata(0,'Link7_data');

rmappdata(0,'ThetaOld');

rmappdata(0,'Area_data');

rmappdata(0,'patch_h');

rmappdata(0,'xtrail');

rmappdata(0,'ytrail');

rmappdata(0,'ztrail');

delete(fig_1);

end

%%

function [hout,ax_out] = uibutton(varargin)

%uibutton: Create pushbutton with more flexible labeling than uicontrol.

% Usage:

% uibutton accepts all the same arguments as uicontrol except for the

% following property changes:

%

% Property Values

% ----------- ------------------------------------------------------

% Style 'pushbutton', 'togglebutton' or 'text', default =

% 'pushbutton'.

% String Same as for text() including cell array of strings and

% TeX or LaTeX interpretation.

% Interpreter 'tex', 'latex' or 'none', default = default for text()

%

% Syntax:

% handle = uibutton('PropertyName',PropertyValue,...)

% handle = uibutton(parent,'PropertyName',PropertyValue,...)

% [text_obj,axes_handle] = uibutton('Style','text',...

% 'PropertyName',PropertyValue,...)

%

% uibutton creates a temporary axes and text object containing the text to

% be displayed, captures the axes as an image, deletes the axes and then

% displays the image on the uicontrol. The handle to the uicontrol is

% returned. If you pass in a handle to an existing uicontol as the first

% argument then uibutton will use that uicontrol and not create a new one.

%

% If the Style is set to 'text' then the axes object is not deleted and the

% text object handle is returned (as well as the handle to the axes in a

% second output argument).

%

% See also UICONTROL.

% Version: 1.6, 20 April 2006

% Author: Douglas M. Schwarz

% Email: dmschwarz=ieee*org, dmschwarz=urgrad*rochester*edu

% Real_email = regexprep(Email,{'=','*'},{'@','.'})

% Detect if first argument is a uicontrol handle.

keep_handle = false;

if nargin > 0

h = varargin{1};

if isscalar(h) && ishandle(h) && strcmp(get(h,'Type'),'uicontrol')

keep_handle = true;

varargin(1) = [];

end

end

% Parse arguments looking for 'Interpreter' property. If found, note its

% value and then remove it from where it was found.

interp_value = get(0,'DefaultTextInterpreter');

arg = 1;

remove = [];

while arg <= length(varargin)

v = varargin{arg};

if isstruct(v)

fn = fieldnames(v);

for i = 1:length(fn)

if strncmpi(fn{i},'interpreter',length(fn{i}))

interp_value = v.(fn{i});

v = rmfield(v,fn{i});

end

end

varargin{arg} = v;

arg = arg + 1;

elseif ischar(v)

if strncmpi(v,'interpreter',length(v))

interp_value = varargin{arg+1};

remove = [remove,arg,arg+1];

end

arg = arg + 2;

elseif arg == 1 && isscalar(v) && ishandle(v) && ...

any(strcmp(get(h,'Type'),{'figure','uipanel'}))

arg = arg + 1;

else

error('Invalid property or uicontrol parent.')

end

end

varargin(remove) = [];

% Create uicontrol, get its properties then hide it.

if keep_handle

set(h,varargin{:})

else

h = uicontrol(varargin{:});

end

s = get(h);

if ~any(strcmp(s.Style,{'pushbutton','togglebutton','text'}))

delete(h)

error('''Style'' must be pushbutton, togglebutton or text.')

end

set(h,'Visible','off')

% Create axes.

parent = get(h,'Parent');

ax = axes('Parent',parent,...

'Units',s.Units,...

---