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[z.facultad/75.68/celdas.git] / trunk / src / breve / robot / Celdas-2-5.tz

@use PhysicalControl.\r
@use Shape.\r
@use Stationary.\r
@use Link.\r
@use MultiBody.\r
@use Drawing.\r
\r
@define CELDAS_MAX_VELOCITY 30.\r
\r
PhysicalControl : CeldasControl {\r
        % This class is used for building simple vehicle \r
        % simulations.  To create a vehicle simulation, \r
        % subclass CeldasControl and use the init method to \r
        % create OBJECT(CeldasObstacle) and \r
        % OBJECT(CeldasVehicle) objects.\r
\r
        + variables:\r
                floor (object).\r
                floorShape (object).\r
                cloudTexture (object).\r
\r
\r
        + to init:\r
                self enable-lighting.\r
                #self enable-smooth-drawing.\r
\r
                floorShape = new Shape.\r
                floorShape init-with-cube size (200, .2, 200).\r
\r
                floor = new Stationary.\r
                floor register with-shape floorShape at-location (0, 0, 0).\r
                #floor catch-shadows.\r
\r
                self point-camera at (0, 0, 0) from (3, 3, 24).\r
\r
                #self enable-shadows.\r
                #self enable-reflections.\r
\r
                cloudTexture = (new Image load from "images/clouds.png"). \r
                self set-background-color to (.4, .6, .9).\r
                self set-background-texture-image to cloudTexture.\r
\r
}\r
\r
MultiBody : CeldasLightVehicle (aka CeldasLightVehicles) {\r
        % This object is used in conjunction with OBJECT(CeldasControl) to\r
        % create simple vehicles.\r
\r
        + variables:\r
                bodyShape (object).\r
                wheelShape (object).\r
                sensorShape (object).\r
                bodyLink (object).\r
\r
                wheels (list).\r
                sensors (list).\r
\r
        + to init:\r
                bodyShape = new Shape.\r
                bodyShape init-with-cube size (4.0, .75, 3.0).  \r
\r
                wheelShape = new Shape.\r
                wheelShape init-with-polygon-disk radius ( self get-wheel-radius ) sides 20 height ( self get-wheel-width ).\r
                # 40\r
\r
                sensorShape = new Shape.\r
                sensorShape init-with-polygon-cone radius .2 sides 5 height .5.\r
                # 10\r
\r
                bodyShape set-density to ( self get-density ).\r
                bodyLink = new Link.\r
                bodyLink set-shape to bodyShape.        \r
                bodyLink set-mu to -1.0.\r
                bodyLink set-eT to .8.\r
\r
                self set-root to bodyLink.\r
\r
                self move to (0, 0.9, 0).\r
                self set-texture-scale to 1.5.\r
\r
        - to get-density:\r
                return 1.0.\r
\r
        - to get-wheel-width:\r
                return 0.1.\r
\r
        - to get-wheel-radius:\r
                return 0.6.\r
\r
        + section "Adding Wheels and Sensors to a Vehicle"\r
\r
        + to add-wheel at location (vector):\r
                % Adds a wheel at location on the vehicle.  This method returns\r
                % the wheel which is created, a OBJECT(CeldasWheel).\r
\r
                wheel, joint (object).\r
\r
                wheel = new CeldasWheel.\r
                wheel set-shape to wheelShape.\r
\r
                joint = new RevoluteJoint.\r
\r
                joint set-relative-rotation around-axis (1, 0, 0) by 1.5708.\r
                joint link parent bodyLink to-child wheel with-normal (0, 0, 1)\r
                                        with-parent-point location with-child-point (0, 0, 0).\r
\r
                wheel set-eT to .8.\r
                wheel set-texture to 0.\r
                wheel set-joint to joint.\r
                joint set-strength-limit to (joint get-strength-hard-limit) / 2.\r
                wheel set-color to (.6, .6, .6).\r
                wheel set-mu to 100000.\r
\r
                self add-dependency on joint.\r
                self add-dependency on wheel.\r
\r
                push wheel onto wheels.\r
\r
                return wheel.\r
\r
        + to add-sensor at location (vector) with-direction direction = (0,1,0)(vector) :\r
                % Adds a sensor at location on the vehicle.  This method returns\r
                % the sensor which is created, a OBJECT(CeldasSensor).\r
\r
                sensor, joint (object).\r
\r
                sensor = new CeldasSensor.\r
                sensor set-direction to direction.\r
                \r
                sensor set-shape to sensorShape.\r
\r
                joint = new RevoluteJoint.\r
\r
                joint set-relative-rotation around-axis (0, 0, 1) by -1.57.\r
                joint link parent bodyLink to-child sensor with-normal (1, 0, 0)\r
                                        with-parent-point location with-child-point (0, 0, 0).\r
\r
                joint set-double-spring with-strength 300 with-max 0.01 with-min -0.01.\r
\r
                self add-dependency on joint.\r
                self add-dependency on sensor.\r
\r
                sensor set-color to (0, 0, 0).\r
\r
                #push sensor onto sensors.\r
\r
                return sensor.\r
\r
        + to destroy:\r
                free sensorShape.\r
                free wheelShape.\r
                free bodyShape.\r
\r
                super destroy.\r
}\r
\r
CeldasLightVehicle : CeldasVehicle (aka CeldasVehicles) {\r
        % A heavy duty version of OBJECT(CeldasLightVehicle), this\r
        % vehicle is heavier and harder to control, but more stable\r
        % at higher speeds.\r
        +variables:\r
            lSensor, rSensor, fSensor, bSensor (object).\r
            lWheel,rWheel (object).        \r
        \r
        - to get-density:\r
                return 20.0.\r
\r
        - to get-wheel-width:\r
                return 0.4.\r
\r
        - to get-wheel-radius:\r
                return 0.8.\r
\r
        + to set-global-velocity to velocity (float):\r
                rWheel set-velocity to velocity.\r
                lWheel set-velocity to velocity.\r
\r
        + to get-global-velocity:\r
                return ((rWheel get-velocity) + (lWheel get-velocity)) / 2.\r
\r
        + to turn-right with-velocity velocity (float):         \r
                lWheel set-velocity to velocity.\r
                rWheel set-velocity to -velocity.\r
\r
        + to turn-left with-velocity velocity (float):\r
#                vehicle rotate around-axis (0,1,0) by 1. \r
                lWheel set-velocity to -velocity.       \r
                rWheel set-velocity to velocity.\r
\r
        + to get-sensor-value:\r
                return (fSensor get-sensor-value).\r
\r
        +to init:\r
            fSensor = (self add-sensor at (2.0, .4, 0)).            \r
            fSensor set-direction to (1,0,0).\r
            fSensor set-id at 1.\r
            fSensor set-body at self.\r
            bSensor = (self add-sensor at (-2.0, .4, 0)).\r
            bSensor set-direction to (-1,0,0).\r
            bSensor set-id at 2.\r
            bSensor set-body at self.\r
            lSensor = (self add-sensor at (0, .4, 1.5)).\r
            lSensor set-direction to (0,0,1).\r
            lSensor set-id at 3.\r
            lSensor set-body at self.\r
\r
\r
            rSensor = (self add-sensor at (0, .4, -1.5)).\r
            rSensor set-direction to (0,0,-1).\r
            rSensor set-id at 4.\r
            rSensor set-body at self.\r
\r
            lWheel  = (self add-wheel at (0, 0, -1.5)).\r
            rWheel  = (self add-wheel at (0, 0, 1.5)).\r
                        \r
        +to iterate:            \r
        #+ to post-iterate:\r
                valuef,valueb,valuer,valuel (float).\r
                fl, fr(float).\r
                \r
                valuef=fSensor get-data.\r
                valueb=bSensor get-data.\r
                valuel=lSensor get-data.\r
                valuer=rSensor get-data.\r
\r
                self turn-left with-velocity(20).\r
                self set-global-velocity to (15).\r
                if valuef >7:           \r
                    self set-global-velocity to (15).\r
                else if (valuef <=7) && (valuef > 0):\r
                {   \r
                    self set-global-velocity to (0).\r
                    #self turn-left with-velocity(2).\r
                    #self turn-right with-velocity(2).\r
                    #self set-global-velocity to (0).\r
                }\r
                #print "sensor valuef: $valuef  valueb: $valueb".\r
                \r
                #else if value < 0.1: self turn-left with-velocity CELDAS_MAX_TURN_VELOCITY.\r
                #else if value > 10: self set-global-velocity to ((self get-global-velocity) - 1).\r
\r
                #fl = (flWheel get-velocity).\r
                #fr = (frWheel get-velocity).\r
                #print " sensorf: $value  sensorb $valueb, fr: $fr, fl: $fl".            \r
            \r
}\r
\r
Stationary : CeldasObstacle (aka CeldasObstacles) {\r
        % A CeldasObstacle is used in conjunction with OBJECT(CeldasControl)\r
        % and OBJECT(CeldasVehicle).  It is what the OBJECT(CeldasSensor)\r
        % objects on the CeldasVehicle detect.\r
        % <p>\r
        % There are no special behaviors associated with the walls--they're \r
        % basically just plain OBJECT(Stationary) objects.\r
   \r
        +variables:\r
            large (float).\r
            direction (vector). \r
\r
\r
        + to init with-size theSize = (10, 3, .1) (vector) with-color theColor = (1, 0, 0) (vector) at-location theLocation = (0, 0, 0) (vector) with-rotation theRotation = [ ( 0, 0, 1 ), ( 0, 1, 0 ), ( 1, 0, 0 ) ] (matrix):                    \r
                self init-with-shape shape (new Shape init-with-cube size theSize) color theColor at-location theLocation with-rotation theRotation.\r
                large=20.\r
\r
        + to init-with-shape shape theShape (object) color theColor = (1, 0, 0) (vector) at-location theLocation = (0, 0, 0) (vector) with-rotation theRotation = [ ( 1, 0, 0 ), ( 0, 1, 0 ), ( 0, 0, 1 ) ] (matrix):\r
                self register with-shape theShape at-location theLocation with-rotation theRotation.\r
                self set-color to theColor.\r
                \r
        + to get-large:\r
            return large.\r
\r
        + to set-direction at theDirection (vector):\r
            direction=theDirection.\r
\r
        + to get-direction:\r
            return direction.\r
}\r
\r
Link : CeldasWheel (aka CeldasWheels) {\r
        % A CeldasWheel is used in conjunction with OBJECT(CeldasVehicle)\r
        % to build Celdas vehicles.  This class is typically not instantiated\r
        % manually, since OBJECT(CeldasVehicle) creates one for you when you\r
        % add a wheel to the vehicle.\r
\r
        + variables:\r
                joint (object).\r
                velocity (float).\r
\r
        + to init:\r
                velocity = 0.\r
\r
        - to set-joint to j (object):\r
                % Used internally.\r
\r
                joint = j.\r
\r
        + section "Configuring the Wheel's Velocity"\r
\r
        + to set-velocity to n (float):\r
                % Sets the velocity of this wheel.\r
\r
                if n > CELDAS_MAX_VELOCITY: n = CELDAS_MAX_VELOCITY.\r
                velocity = n.\r
\r
                joint set-joint-velocity to velocity.\r
\r
        + to get-velocity:\r
                % Gets the velocity of this wheel.\r
                \r
                return velocity.\r
\r
}\r
\r
Link : CeldasSensor (aka CeldasSensors) {\r
        % A CeldasSensor is used in conjunction with OBJECT(CeldasVehicle)\r
        % to build Celdas vehicles.  This class is typically not instantiated\r
        % manually, since OBJECT(CeldasVehicle) creates one for you when you\r
        % add a sensor to the vehicle.\r
\r
        + variables:\r
                direction (vector).\r
                positiveDirection(vector).\r
                sensorAngle (float).\r
                value (float).\r
                draw (object).\r
                body(object).\r
                id(int).\r
\r
        + to init :\r
                direction = (1,0,1).\r
                positiveDirection= (1,0,1).\r
                sensorAngle = 1.6.\r
                value = 0.0.\r
                draw = new Drawing.\r
                                \r
\r
  + section "Configuring the Sensor Values"\r
        + to set-id at n (int):\r
            id=n.\r
\r
        + to set-body at robotBody(object):\r
                body=robotBody.\r
                \r
        + to set-sensor-angle to n (float):\r
                % Sets the angle in which this sensor can detect obstacles.  The default\r
                % value of 1.6 means that the sensor can see most of everything in\r
                % front of it.  Setting the value to be any higher leads to general\r
                % wackiness, so I don't suggest it.\r
\r
                sensorAngle = n.\r
\r
        + to set-direction to n (vector):\r
                direction = n.\r
                positiveDirection::x=|n::x|.\r
                positiveDirection::y=|n::y|.\r
                positiveDirection::z=|n::z|.\r
\r
  + section "Getting the Sensor Values"\r
\r
        + to get-sensor-value:\r
                % Gets the sensor value. This should be used from post-iterate,\r
                % if not, the sensor reading correspond to the previous\r
                % iteration.\r
        \r
        #+ to iterate:\r
        \r
        + to get-data:\r
                i (object).\r
                x,y,z (float).\r
                min,dist (float).\r
                v,obs(vector).\r
                aux(float).\r
                j (int).\r
                des1,des2,des3(int).\r
                wallBegin,wallEnd (float).\r
                \r
                aux1,aux2,aux3,aux4 (float).\r
                yo,toObstacle, transDir (vector).\r
                largeWall (float).\r
                source,destiny (vector).\r
                obsLoc (vector).                \r
                location (vector).\r
                posObstacle,posSensor (vector).\r
                                             \r
                draw clear.\r
                value = 0.0.\r
                j=0.\r
                min=0.\r
                foreach i in (all CeldasObstacles): \r
                        {\r
                         posObstacle=i get-location.\r
                         \r
                                                                \r
                        #!\r
                        if(dot((i get-direction),direction)==0):\r
                                des1=1.\r
                        else\r
                                des1=0.\r
                        !#\r
\r
                        des2=0.\r
                        if(dot(direction,(1,1,1))<0):\r
                        {                        \r
                            if((dot((self get-location),positiveDirection))>(dot(posObstacle,positiveDirection))):\r
                                        des2=1.      \r
                        }\r
                        else\r
                        {\r
                            if((dot((self get-location),positiveDirection))<(dot(posObstacle,positiveDirection))):\r
                                        des2=1.         \r
                        }                       \r
\r
\r
                        #Compruebo que el robot este frente a la pared\r
                        wallBegin=dot((i get-location),(i get-direction) )- (i get-large)/2.\r
                        wallEnd=dot((i get-location),(i get-direction) )+ (i get-large)/2.              \r
\r
\r
                        #print "begin: $wallBegin end: $wallEnd".\r
                        yo=self get-location.\r
                        destiny=i get-direction.\r
\r
                        v = (body get-location) - (self get-location ).\r
                        obsLoc::y=y=posObstacle::y.                                                             \r
                                \r
                        if (dot((i get-direction),(1,0,0))):\r
                        {\r
                         obsLoc::x=x=((self get-location)::x + ((posObstacle::z - (self get-location)::z)*v::x/v::z)).\r
                         obsLoc::z=z=posObstacle::z.\r
                        }                               \r
                        else\r
                        {\r
                         obsLoc::z=z=((self get-location)::z + ((posObstacle::x - (self get-location)::x)*v::z/v::x)).\r
                         obsLoc::x=x=posObstacle::x.\r
                        }                                                       \r
\r
\r
                        if (dot((obsLoc),(i get-direction)) > wallBegin) && (dot((obsLoc),(i get-direction)) < wallEnd):\r
                                des3=1.\r
                        else\r
                        {\r
                                 des3=0.\r
                                 \r
                        }                               \r
\r
                        aux1=dot((self get-location),(i get-direction)).\r
\r
                        #print "sensor: $id obstaculo: $posObstacle direP: $destiny direS: $direction yo: $yo ".\r
                        #print "dist: $aux1 begin: $wallBegin end: $wallEnd".\r
\r
                       \r
                        print "sensor: $id , des1: $des1, des2: $des2, des3: $des3".\r
                        if ((des2) && (des3)):\r
                         {                                    \r
                                draw clear.                             \r
                                #print " posObstacle: $posObstacle".                                                    \r
                                                        \r
                                dist=|obsLoc - (self get-location)|.\r
                                if( (j==0) || (min>dist) ):\r
                                 {\r
                                        min=dist.\r
                                        obs=obsLoc.\r
                                        j++.    \r
                                 }\r
\r
                         }                                              \r
\r
                        \r
                } #end for\r
\r
                if(j!=0):\r
                        {\r
                          #Dibujo el laser\r
                          draw set-color to (1, 0, 0).\r
                          draw draw-line from (self get-location) to (obs).\r
                          return dist.\r
                        }\r
                \r
\r
                value = -1.\r
                return value.\r
\r
\r
}\r