new prototype for VisualISAM_gui from Frank's example with many options

2012-06-08 16:40:30 +00:00 · 2012-06-08 16:40:30 +00:00 · 2f2f1875d9
parent 1913640d2c
commit 2f2f1875d9
13 changed files with 351 additions and 3 deletions
--- a/matlab/examples/VisualISAM_gui/VisualISAMData_cube.m
+++ b/matlab/examples/VisualISAM_gui/VisualISAMData_cube.m
--- a/matlab/examples/VisualISAM_gui/VisualISAMData_triangle.m
+++ b/matlab/examples/VisualISAM_gui/VisualISAMData_triangle.m
--- a/matlab/examples/VisualISAM_gui/VisualISAMExample_triangle2.m
+++ b/matlab/examples/VisualISAM_gui/VisualISAMExample_triangle2.m
@ -1,16 +1,22 @@
 %% data
-data = VisualISAMData_triangle();
+%data = VisualISAMData_triangle();
 data = VisualISAMData_cube();
 %% init
 [isam results] = VisualISAMInitialize(data);
 sprintf('Frame 1,2:')
 results
 figure(1); clf;
 VisualISAMPlot(results, data);
 %% Next frame index
-frame_i=3; 
+frame_i=2; 
 %% All steps
 while (frame_i<size(data.cameras,2))
    %% one step
-    [isam results] = VisualISAMStep(frame_i, isam, data, results); frame_i = frame_i+1;
+    frame_i = frame_i+1;
    [isam results] = VisualISAMStep(frame_i, isam, data, results); 
    results
    figure(1); clf;
    VisualISAMPlot(results, data);
 end
--- a/matlab/examples/VisualISAM_gui/VisualISAMInitialize.m
+++ b/matlab/examples/VisualISAM_gui/VisualISAMInitialize.m
--- a/matlab/examples/VisualISAM_gui/VisualISAMPlot.m
+++ b/matlab/examples/VisualISAM_gui/VisualISAMPlot.m
--- a/matlab/examples/VisualISAM_gui/VisualISAMStep.m
+++ b/matlab/examples/VisualISAM_gui/VisualISAMStep.m
--- a/matlab/examples/VisualISAM_gui/VisualISAM_gui.fig
+++ b/matlab/examples/VisualISAM_gui/VisualISAM_gui.fig
--- a/matlab/examples/VisualISAM_gui/VisualISAM_gui.m
+++ b/matlab/examples/VisualISAM_gui/VisualISAM_gui.m
--- a/matlab/examples/VisualISAM_gui2/VisualISAM_gui.fig
+++ b/matlab/examples/VisualISAM_gui2/VisualISAM_gui.fig
--- a/matlab/examples/VisualISAM_gui2/VisualISAM_gui.m
+++ b/matlab/examples/VisualISAM_gui2/VisualISAM_gui.m
@ -0,0 +1,175 @@
 function varargout = VisualISAM_gui(varargin)
 % VISUALISAM_GUI MATLAB code for VisualISAM_gui.fig
 %      VISUALISAM_GUI, by itself, creates a new VISUALISAM_GUI or raises the existing
 %      singleton*.
 %
 %      H = VISUALISAM_GUI returns the handle to a new VISUALISAM_GUI or the handle to
 %      the existing singleton*.
 %
 %      VISUALISAM_GUI('CALLBACK',hObject,eventData,handles,...) calls the local
 %      function named CALLBACK in VISUALISAM_GUI.M with the given input arguments.
 %
 %      VISUALISAM_GUI('Property','Value',...) creates a new VISUALISAM_GUI or raises the
 %      existing singleton*.  Starting from the left, property value pairs are
 %      applied to the GUI before VisualISAM_gui_OpeningFcn gets called.  An
 %      unrecognized property name or invalid value makes property application
 %      stop.  All inputs are passed to VisualISAM_gui_OpeningFcn via varargin.
 %
 %      *See GUI Options on GUIDE's Tools menu.  Choose "GUI allows only one
 %      instance to run (singleton)".
 %
 % See also: GUIDE, GUIDATA, GUIHANDLES
 % Edit the above text to modify the response to help VisualISAM_gui
 % Last Modified by GUIDE v2.5 08-Jun-2012 12:35:14
 % Begin initialization code - DO NOT EDIT
 gui_Singleton = 1;
 gui_State = struct('gui_Name',       mfilename, ...
                   'gui_Singleton',  gui_Singleton, ...
                   'gui_OpeningFcn', @VisualISAM_gui_OpeningFcn, ...
                   'gui_OutputFcn',  @VisualISAM_gui_OutputFcn, ...
                   'gui_LayoutFcn',  [] , ...
                   'gui_Callback',   []);
 if nargin && ischar(varargin{1})
    gui_State.gui_Callback = str2func(varargin{1});
 end
 if nargout
    [varargout{1:nargout}] = gui_mainfcn(gui_State, varargin{:});
 else
    gui_mainfcn(gui_State, varargin{:});
 end
 % End initialization code - DO NOT EDIT
 % --- Executes just before VisualISAM_gui is made visible.
 function VisualISAM_gui_OpeningFcn(hObject, eventdata, handles, varargin)
 % This function has no output args, see OutputFcn.
 % hObject    handle to figure
 % eventdata  reserved - to be defined in a future version of MATLAB
 % handles    structure with handles and user data (see GUIDATA)
 % varargin   command line arguments to VisualISAM_gui (see VARARGIN)
 % Choose default command line output for VisualISAM_gui
 %% Data Options
 handles.TRIANGLE = true;
 handles.NCAMERAS = 20;
 handles.SHOW_IMAGES = false;
 %% iSAM Options
 handles.HARD_CONSTRAINT = false;
 handles.POINT_PRIORS = false;
 handles.BATCH_INIT = true;
 handles.REORDER_INTERVAL=10;
 handles.ALWAYS_RELINEARIZE = false;
 %% Display Options
 handles.SAVE_GRAPH = false;
 handles.PRINT_STATS = true;
 handles.DRAW_INTERVAL = 1;
 handles.CAMERA_INTERVAL = 1;
 handles.DRAW_TRUE_POSES = false;
 handles.SAVE_FIGURES = false;
 handles.SAVE_GRAPHS = false;
 handles = vData(handles);
 handles = vInit(handles);
 handles.output = hObject;
 % Update handles structure
 guidata(hObject, handles);
 % UIWAIT makes VisualISAM_gui wait for user response (see UIRESUME)
 % uiwait(handles.figure1);
 % --- Outputs from this function are returned to the command line.
 function varargout = VisualISAM_gui_OutputFcn(hObject, eventdata, handles) 
 % varargout  cell array for returning output args (see VARARGOUT);
 % hObject    handle to figure
 % eventdata  reserved - to be defined in a future version of MATLAB
 % handles    structure with handles and user data (see GUIDATA)
 % Get default command line output from handles structure
 varargout{1} = handles.output;
 function handles = initialize(handles)
    handles=vData(handles);
    handles=vInit(handles);
    handles.result = {};
    cla;
    handles
 % --- Executes on button press in intializeButton.
 function intializeButton_Callback(hObject, eventdata, handles)
 % hObject    handle to intializeButton (see GCBO)
 % eventdata  reserved - to be defined in a future version of MATLAB
 % handles    structure with handles and user data (see GUIDATA)
    handles=initialize(handles)
    guidata(hObject,handles)
 % --- Executes on button press in stepButton.
 function stepButton_Callback(hObject, eventdata, handles)
 % hObject    handle to stepButton (see GCBO)
 % eventdata  reserved - to be defined in a future version of MATLAB
 % handles    structure with handles and user data (see GUIDATA)
    if (handles.frame_i<handles.NCAMERAS)
        sprintf('Frame %d:', handles.frame_i)
        handles = vStep(handles);
        guidata(hObject,handles)
    end
 % --- Executes on selection change in popupmenu1.
 function popupmenu1_Callback(hObject, eventdata, handles)
 % hObject    handle to popupmenu1 (see GCBO)
 % eventdata  reserved - to be defined in a future version of MATLAB
 % handles    structure with handles and user data (see GUIDATA)
 % Hints: contents = cellstr(get(hObject,'String')) returns popupmenu1 contents as cell array
 %        contents{get(hObject,'Value')} returns selected item from popupmenu1
    str = cellstr(get(hObject,'String'));
    sel = get(hObject,'Value');
    switch str{sel}
        case 'triangle'
            handles.TRIANGLE = true
        case 'cube'
            handles.TRIANGLE = false
    end
    handles = initialize(handles);
    guidata(hObject, handles);
 % --- Executes during object creation, after setting all properties.
 function popupmenu1_CreateFcn(hObject, eventdata, handles)
 % hObject    handle to popupmenu1 (see GCBO)
 % eventdata  reserved - to be defined in a future version of MATLAB
 % handles    empty - handles not created until after all CreateFcns called
 % Hint: popupmenu controls usually have a white background on Windows.
 %       See ISPC and COMPUTER.
 if ispc && isequal(get(hObject,'BackgroundColor'), get(0,'defaultUicontrolBackgroundColor'))
    set(hObject,'BackgroundColor','white');
 end
 % --- Executes on button press in backButton.
 function backButton_Callback(hObject, eventdata, handles)
 % hObject    handle to backButton (see GCBO)
 % eventdata  reserved - to be defined in a future version of MATLAB
 % handles    structure with handles and user data (see GUIDATA)
    sprintf('Not yet implemented')
 % --- Executes on button press in runButton.
 function runButton_Callback(hObject, eventdata, handles)
 % hObject    handle to runButton (see GCBO)
 % eventdata  reserved - to be defined in a future version of MATLAB
 % handles    structure with handles and user data (see GUIDATA)
    sprintf('Not yet implemented')
 % --- Executes on button press in stopButton.
 function stopButton_Callback(hObject, eventdata, handles)
 % hObject    handle to stopButton (see GCBO)
 % eventdata  reserved - to be defined in a future version of MATLAB
 % handles    structure with handles and user data (see GUIDATA)
    sprintf('Not yet implemented')
--- a/matlab/examples/VisualISAM_gui2/vData.m
+++ b/matlab/examples/VisualISAM_gui2/vData.m
@ -0,0 +1,51 @@
 function [ handles ] = vData( handles )
 %VDATA Summary of this function goes here
 %   Detailed explanation goes here
 %% Generate simulated data
 if handles.TRIANGLE % Create a triangle target, just 3 points on a plane
    handles.nPoints = 3;
    r = 10;
    for j=1:handles.nPoints
        theta = (j-1)*2*pi/handles.nPoints;
        handles.points{j} = gtsamPoint3([r*cos(theta), r*sin(theta), 0]');
    end
 else % 3D landmarks as vertices of a cube
    handles.nPoints = 8;
    handles.points = {gtsamPoint3([10 10 10]'),...
        gtsamPoint3([-10 10 10]'),...
        gtsamPoint3([-10 -10 10]'),...
        gtsamPoint3([10 -10 10]'),...
        gtsamPoint3([10 10 -10]'),...
        gtsamPoint3([-10 10 -10]'),...
        gtsamPoint3([-10 -10 -10]'),...
        gtsamPoint3([10 -10 -10]')};
 end
 %% Create camera cameras on a circle around the triangle
 height = 10; r = 40;
 handles.K = gtsamCal3_S2(500,500,0,640/2,480/2);
 for i=1:handles.NCAMERAS
    theta = (i-1)*2*pi/handles.NCAMERAS;
    t = gtsamPoint3([r*cos(theta), r*sin(theta), height]');
    handles.cameras{i} = gtsamSimpleCamera_lookat(t, gtsamPoint3, gtsamPoint3([0,0,1]'), handles.K);
 %     if handles.SHOW_IMAGES % show images
 %         figure(2+i);clf;hold on
 %         set(2+i,'NumberTitle','off','Name',sprintf('Camera %d',i));
 %         for j=1:nPoints
 %             zij = handles.cameras{i}.project(handles.points{j});
 %             plot(zij.x,zij.y,'*');
 %             axis([1 640 1 480]);
 %         end
 %     end
 end
 handles.odometry = handles.cameras{1}.pose.between(handles.cameras{2}.pose);
 %% Set Noise parameters
 handles.poseNoise = gtsamSharedNoiseModel_Sigmas([0.001 0.001 0.001 0.1 0.1 0.1]');
 handles.odometryNoise = gtsamSharedNoiseModel_Sigmas([0.001 0.001 0.001 0.1 0.1 0.1]');
 handles.pointNoise = gtsamSharedNoiseModel_Sigma(3, 0.1);
 handles.measurementNoise = gtsamSharedNoiseModel_Sigma(2, 1.0);
 end
--- a/matlab/examples/VisualISAM_gui2/vInit.m
+++ b/matlab/examples/VisualISAM_gui2/vInit.m
@ -0,0 +1,31 @@
 function [ handles ] = vInit( handles )
 %VINIT Summary of this function goes here
 %   Detailed explanation goes here
 %% Initialize iSAM
 handles.isam = visualSLAMISAM(handles.REORDER_INTERVAL);
 handles.newFactors = visualSLAMGraph;
 handles.initialEstimates = visualSLAMValues;
 i1 = symbol('x',1);
 camera1 = handles.cameras{1};
 pose1 = camera1.pose;
 if handles.HARD_CONSTRAINT % add hard constraint
    handles.newFactors.addPoseConstraint(i1,pose1);
 else
    handles.newFactors.addPosePrior(i1,pose1, handles.poseNoise);
 end
 handles.initialEstimates.insertPose(i1,pose1);
 % Add visual measurement factors from first pose
 for j=1:handles.nPoints
    jj = symbol('l',j);
    if handles.POINT_PRIORS % add point priors
        handles.newFactors.addPointPrior(jj, handles.points{j}, handles.pointNoise);
    end
    zij = camera1.project(handles.points{j});
    handles.newFactors.addMeasurement(zij, handles.measurementNoise, i1, jj, handles.K);
    handles.initialEstimates.insertPoint(jj, handles.points{j});
 end
 handles.frame_i = 2;
 end
--- a/matlab/examples/VisualISAM_gui2/vStep.m
+++ b/matlab/examples/VisualISAM_gui2/vStep.m
@ -0,0 +1,85 @@
 function [ handles ] = vStep( handles )
 %VSTEP Summary of this function goes here
 %   Detailed explanation goes here
    %% Add odometry
    handles.newFactors.addOdometry(symbol('x',handles.frame_i-1), symbol('x',handles.frame_i), handles.odometry, handles.odometryNoise);
    %% Add visual measurement factors
    for j=1:handles.nPoints
        zij = handles.cameras{handles.frame_i}.project(handles.points{j});
        handles.newFactors.addMeasurement(zij, handles.measurementNoise, symbol('x',handles.frame_i), symbol('l',j), handles.K);
    end
    %% Initial estimates for the new pose. Also initialize points while in the first frame.
    %TODO: this might be suboptimal since "result" is not the fully optimized result
    handles.frame_i
    if (handles.frame_i==2), prevPose = handles.cameras{1}.pose;
    else, prevPose = handles.result.pose(symbol('x',handles.frame_i-1)); end
    handles.initialEstimates.insertPose(symbol('x',handles.frame_i), prevPose.compose(handles.odometry));
    %% Update ISAM
    if handles.BATCH_INIT & (handles.frame_i==2) % Do a full optimize for first two poses
        handles.initialEstimates
        fullyOptimized = handles.newFactors.optimize(handles.initialEstimates)
        handles.initialEstimates = fullyOptimized;
    end
 %     figure(1);tic;
    handles.isam.update(handles.newFactors, handles.initialEstimates);
 %     t=toc; plot(handles.frame_i,t,'r.'); tic
    handles.result = handles.isam.estimate();
 %     t=toc; plot(handles.frame_i,t,'g.');
    if handles.ALWAYS_RELINEARIZE % re-linearize
        handles.isam.reorder_relinearize();
    end
    if handles.SAVE_GRAPH
        handles.isam.saveGraph(sprintf('VisualiSAM.dot',handles.frame_i));
    end
    if handles.PRINT_STATS
        handles.isam.printStats();
    end
    handles.frame_i
    handles.DRAW_INTERVAL
    if mod(handles.frame_i,handles.DRAW_INTERVAL)==0
        sprintf('Plotting')
        %% Plot results
        tic
 %         h=figure(2);clf
 %         set(1,'NumberTitle','off','Name','Visual iSAM');
        hold on;
        for j=1:handles.nPoints
            P = handles.isam.marginalCovariance(symbol('l',j));
            point_j = handles.result.point(symbol('l',j));
            plot3(point_j.x, point_j.y, point_j.z,'marker','o');
            covarianceEllipse3D([point_j.x;point_j.y;point_j.z],P);
        end
        for ii=1:handles.CAMERA_INTERVAL:handles.frame_i
            P = handles.isam.marginalCovariance(symbol('x',ii));
            pose_ii = handles.result.pose(symbol('x',ii));
            plotPose3(pose_ii,P,10);
            if handles.DRAW_TRUE_POSES % show ground truth
                plotPose3(handles.cameras{ii}.pose,0.001*eye(6),10);
            end
        end
        axis([-40 40 -40 40 -10 20]);axis equal
        view(3)
        colormap('hot')
 %         figure(2);
        t=toc;
        if handles.DRAW_INTERVAL~=handles.NCAMERAS, plot(handles.frame_i,t,'b.'); end
        if handles.SAVE_FIGURES
            print(h,'-dpng',sprintf('VisualiSAM%03d.png',handles.frame_i));
        end
        if handles.SAVE_GRAPHS
            handles.isam.saveGraph(sprintf('VisualiSAM%03d.dot',handles.frame_i));
        end
        hold off;
    end
    %% Reset newFactors and initialEstimates to prepare for the next update
    handles.newFactors = visualSLAMGraph;
    handles.initialEstimates = visualSLAMValues;
 	handles.frame_i = handles.frame_i+1;
 end