cortex: org/sense.org annotate

annotate org/sense.org @ 309:5d448182c807

added/verified YouTube backup links for all videos.

author	Robert McIntyre <rlm@mit.edu>
date	Sat, 18 Feb 2012 11:42:34 -0700
parents	7e7f8d6d9ec5
children	2c7fbcbd5ebb

rev	line source
rlm@202	1 #+title: Helper Functions / Motivations
rlm@151	2 #+author: Robert McIntyre
rlm@151	3 #+email: rlm@mit.edu
rlm@151	4 #+description: sensory utilities
rlm@151	5 #+keywords: simulation, jMonkeyEngine3, clojure, simulated senses
rlm@151	6 #+SETUPFILE: ../../aurellem/org/setup.org
rlm@151	7 #+INCLUDE: ../../aurellem/org/level-0.org
rlm@151	8
rlm@197	9 * Blender Utilities
rlm@306	10 In blender, any object can be assigned an arbitrary number of key-value
rlm@306	11 pairs which are called "Custom Properties". These are accessible in
rlm@306	12 jMonkeyEngine when blender files are imported with the
rlm@273	13 =BlenderLoader=. =meta-data= extracts these properties.
rlm@198	14
rlm@198	15 #+name: blender-1
rlm@197	16 #+begin_src clojure
rlm@181	17 (defn meta-data
rlm@181	18 "Get the meta-data for a node created with blender."
rlm@181	19 [blender-node key]
rlm@151	20 (if-let [data (.getUserData blender-node "properties")]
rlm@198	21 (.findValue data key) nil))
rlm@198	22 #+end_src
rlm@151	23
rlm@198	24 Blender uses a different coordinate system than jMonkeyEngine so it
rlm@198	25 is useful to be able to convert between the two. These only come into
rlm@198	26 play when the meta-data of a node refers to a vector in the blender
rlm@198	27 coordinate system.
rlm@198	28
rlm@198	29 #+name: blender-2
rlm@198	30 #+begin_src clojure
rlm@197	31 (defn jme-to-blender
rlm@197	32 "Convert from JME coordinates to Blender coordinates"
rlm@197	33 [#^Vector3f in]
rlm@198	34 (Vector3f. (.getX in) (- (.getZ in)) (.getY in)))
rlm@151	35
rlm@197	36 (defn blender-to-jme
rlm@197	37 "Convert from Blender coordinates to JME coordinates"
rlm@197	38 [#^Vector3f in]
rlm@198	39 (Vector3f. (.getX in) (.getZ in) (- (.getY in))))
rlm@197	40 #+end_src
rlm@197	41
rlm@198	42 * Sense Topology
rlm@198	43
rlm@198	44 Human beings are three-dimensional objects, and the nerves that
rlm@198	45 transmit data from our various sense organs to our brain are
rlm@198	46 essentially one-dimensional. This leaves up to two dimensions in which
rlm@198	47 our sensory information may flow. For example, imagine your skin: it
rlm@198	48 is a two-dimensional surface around a three-dimensional object (your
rlm@198	49 body). It has discrete touch sensors embedded at various points, and
rlm@198	50 the density of these sensors corresponds to the sensitivity of that
rlm@198	51 region of skin. Each touch sensor connects to a nerve, all of which
rlm@198	52 eventually are bundled together as they travel up the spinal cord to
rlm@198	53 the brain. Intersect the spinal nerves with a guillotining plane and
rlm@198	54 you will see all of the sensory data of the skin revealed in a roughly
rlm@198	55 circular two-dimensional image which is the cross section of the
rlm@198	56 spinal cord. Points on this image that are close together in this
rlm@198	57 circle represent touch sensors that are /probably/ close together on
rlm@306	58 the skin, although there is of course some cutting and rearrangement
rlm@198	59 that has to be done to transfer the complicated surface of the skin
rlm@198	60 onto a two dimensional image.
rlm@198	61
rlm@198	62 Most human senses consist of many discrete sensors of various
rlm@198	63 properties distributed along a surface at various densities. For
rlm@198	64 skin, it is Pacinian corpuscles, Meissner's corpuscles, Merkel's
rlm@198	65 disks, and Ruffini's endings, which detect pressure and vibration of
rlm@198	66 various intensities. For ears, it is the stereocilia distributed
rlm@198	67 along the basilar membrane inside the cochlea; each one is sensitive
rlm@198	68 to a slightly different frequency of sound. For eyes, it is rods
rlm@198	69 and cones distributed along the surface of the retina. In each case,
rlm@198	70 we can describe the sense with a surface and a distribution of sensors
rlm@198	71 along that surface.
rlm@198	72
rlm@198	73 ** UV-maps
rlm@198	74
rlm@198	75 Blender and jMonkeyEngine already have support for exactly this sort
rlm@198	76 of data structure because it is used to "skin" models for games. It is
rlm@201	77 called [[http://wiki.blender.org/index.php/Doc:2.6/Manual/Textures/Mapping/UV][UV-mapping]]. The three-dimensional surface of a model is cut
rlm@201	78 and smooshed until it fits on a two-dimensional image. You paint
rlm@201	79 whatever you want on that image, and when the three-dimensional shape
rlm@201	80 is rendered in a game the smooshing and cutting us reversed and the
rlm@201	81 image appears on the three-dimensional object.
rlm@198	82
rlm@198	83 To make a sense, interpret the UV-image as describing the distribution
rlm@198	84 of that senses sensors. To get different types of sensors, you can
rlm@198	85 either use a different color for each type of sensor, or use multiple
rlm@198	86 UV-maps, each labeled with that sensor type. I generally use a white
rlm@306	87 pixel to mean the presence of a sensor and a black pixel to mean the
rlm@306	88 absence of a sensor, and use one UV-map for each sensor-type within a
rlm@198	89 given sense. The paths to the images are not stored as the actual
rlm@198	90 UV-map of the blender object but are instead referenced in the
rlm@198	91 meta-data of the node.
rlm@198	92
rlm@306	93 #+CAPTION: The UV-map for an elongated icososphere. The white dots each represent a touch sensor. They are dense in the regions that describe the tip of the finger, and less dense along the dorsal side of the finger opposite the tip.
rlm@198	94 #+ATTR_HTML: width="300"
rlm@198	95 [[../images/finger-UV.png]]
rlm@198	96
rlm@198	97 #+CAPTION: Ventral side of the UV-mapped finger. Notice the density of touch sensors at the tip.
rlm@198	98 #+ATTR_HTML: width="300"
rlm@198	99 [[../images/finger-1.png]]
rlm@198	100
rlm@198	101 #+CAPTION: Side view of the UV-mapped finger.
rlm@198	102 #+ATTR_HTML: width="300"
rlm@198	103 [[../images/finger-2.png]]
rlm@198	104
rlm@198	105 #+CAPTION: Head on view of the finger. In both the head and side views you can see the divide where the touch-sensors transition from high density to low density.
rlm@198	106 #+ATTR_HTML: width="300"
rlm@198	107 [[../images/finger-3.png]]
rlm@198	108
rlm@198	109 The following code loads images and gets the locations of the white
rlm@273	110 pixels so that they can be used to create senses. =load-image= finds
rlm@198	111 images using jMonkeyEngine's asset-manager, so the image path is
rlm@198	112 expected to be relative to the =assets= directory. Thanks to Dylan
rlm@273	113 for the beautiful version of =filter-pixels=.
rlm@198	114
rlm@198	115 #+name: topology-1
rlm@197	116 #+begin_src clojure
rlm@197	117 (defn load-image
rlm@197	118 "Load an image as a BufferedImage using the asset-manager system."
rlm@197	119 [asset-relative-path]
rlm@197	120 (ImageToAwt/convert
rlm@197	121 (.getImage (.loadTexture (asset-manager) asset-relative-path))
rlm@197	122 false false 0))
rlm@151	123
rlm@181	124 (def white 0xFFFFFF)
rlm@181	125
rlm@181	126 (defn white? [rgb]
rlm@181	127 (= (bit-and white rgb) white))
rlm@181	128
rlm@151	129 (defn filter-pixels
rlm@151	130 "List the coordinates of all pixels matching pred, within the bounds
rlm@198	131 provided. If bounds are not specified then the entire image is
rlm@198	132 searched.
rlm@182	133 bounds -> [x0 y0 width height]"
rlm@151	134 {:author "Dylan Holmes"}
rlm@151	135 ([pred #^BufferedImage image]
rlm@151	136 (filter-pixels pred image [0 0 (.getWidth image) (.getHeight image)]))
rlm@151	137 ([pred #^BufferedImage image [x0 y0 width height]]
rlm@151	138 ((fn accumulate [x y matches]
rlm@151	139 (cond
rlm@151	140 (>= y (+ height y0)) matches
rlm@151	141 (>= x (+ width x0)) (recur 0 (inc y) matches)
rlm@151	142 (pred (.getRGB image x y))
rlm@151	143 (recur (inc x) y (conj matches [x y]))
rlm@151	144 :else (recur (inc x) y matches)))
rlm@151	145 x0 y0 [])))
rlm@151	146
rlm@151	147 (defn white-coordinates
rlm@151	148 "Coordinates of all the white pixels in a subset of the image."
rlm@151	149 ([#^BufferedImage image bounds]
rlm@181	150 (filter-pixels white? image bounds))
rlm@151	151 ([#^BufferedImage image]
rlm@181	152 (filter-pixels white? image)))
rlm@198	153 #+end_src
rlm@151	154
rlm@198	155 ** Topology
rlm@151	156
rlm@198	157 Information from the senses is transmitted to the brain via bundles of
rlm@198	158 axons, whether it be the optic nerve or the spinal cord. While these
rlm@306	159 bundles more or less preserve the overall topology of a sense's
rlm@306	160 two-dimensional surface, they do not preserve the precise euclidean
rlm@273	161 distances between every sensor. =collapse= is here to smoosh the
rlm@306	162 sensors described by a UV-map into a contiguous region that still
rlm@306	163 preserves the topology of the original sense.
rlm@198	164
rlm@198	165 #+name: topology-2
rlm@198	166 #+begin_src clojure
rlm@235	167 (in-ns 'cortex.sense)
rlm@235	168
rlm@151	169 (defn average [coll]
rlm@151	170 (/ (reduce + coll) (count coll)))
rlm@151	171
rlm@235	172 (defn- collapse-1d
rlm@235	173 "One dimensional helper for collapse."
rlm@151	174 [center line]
rlm@151	175 (let [length (count line)
rlm@151	176 num-above (count (filter (partial < center) line))
rlm@151	177 num-below (- length num-above)]
rlm@151	178 (range (- center num-below)
rlm@151	179 (+ center num-above))))
rlm@151	180
rlm@151	181 (defn collapse
rlm@235	182 "Take a sequence of pairs of integers and collapse them into a
rlm@306	183 contiguous bitmap with no \"holes\" or negative entries, as close to
rlm@235	184 the origin [0 0] as the shape permits. The order of the points is
rlm@235	185 preserved.
rlm@235	186
rlm@235	187 eg.
rlm@235	188 (collapse [[-5 5] [5 5] --> [[0 1] [1 1]
rlm@235	189 [-5 -5] [5 -5]]) --> [0 0] [1 0]]
rlm@235	190
rlm@235	191 (collapse [[-5 5] [-5 -5] --> [[0 1] [0 0]
rlm@235	192 [ 5 -5] [ 5 5]]) --> [1 0] [1 1]]"
rlm@151	193 [points]
rlm@151	194 (if (empty? points) []
rlm@151	195 (let
rlm@151	196 [num-points (count points)
rlm@151	197 center (vector
rlm@151	198 (int (average (map first points)))
rlm@151	199 (int (average (map first points))))
rlm@151	200 flattened
rlm@151	201 (reduce
rlm@151	202 concat
rlm@151	203 (map
rlm@151	204 (fn [column]
rlm@151	205 (map vector
rlm@151	206 (map first column)
rlm@151	207 (collapse-1d (second center)
rlm@151	208 (map second column))))
rlm@151	209 (partition-by first (sort-by first points))))
rlm@151	210 squeezed
rlm@151	211 (reduce
rlm@151	212 concat
rlm@151	213 (map
rlm@151	214 (fn [row]
rlm@151	215 (map vector
rlm@151	216 (collapse-1d (first center)
rlm@151	217 (map first row))
rlm@151	218 (map second row)))
rlm@151	219 (partition-by second (sort-by second flattened))))
rlm@182	220 relocated
rlm@151	221 (let [min-x (apply min (map first squeezed))
rlm@151	222 min-y (apply min (map second squeezed))]
rlm@151	223 (map (fn [[x y]]
rlm@151	224 [(- x min-x)
rlm@151	225 (- y min-y)])
rlm@235	226 squeezed))
rlm@306	227 point-correspondence
rlm@235	228 (zipmap (sort points) (sort relocated))
rlm@235	229
rlm@235	230 original-order
rlm@306	231 (vec (map point-correspondence points))]
rlm@235	232 original-order)))
rlm@198	233 #+end_src
rlm@198	234 * Viewing Sense Data
rlm@151	235
rlm@198	236 It's vital to /see/ the sense data to make sure that everything is
rlm@273	237 behaving as it should. =view-sense= and its helper, =view-image=
rlm@200	238 are here so that each sense can define its own way of turning
rlm@200	239 sense-data into pictures, while the actual rendering of said pictures
rlm@273	240 stays in one central place. =points->image= helps senses generate a
rlm@200	241 base image onto which they can overlay actual sense data.
rlm@198	242
rlm@199	243 #+name: view-senses
rlm@198	244 #+begin_src clojure
rlm@199	245 (in-ns 'cortex.sense)
rlm@198	246
rlm@199	247 (defn view-image
rlm@306	248 "Initializes a JPanel on which you may draw a BufferedImage.
rlm@199	249 Returns a function that accepts a BufferedImage and draws it to the
rlm@199	250 JPanel. If given a directory it will save the images as png files
rlm@199	251 starting at 0000000.png and incrementing from there."
rlm@199	252 ([#^File save]
rlm@199	253 (let [idx (atom -1)
rlm@199	254 image
rlm@199	255 (atom
rlm@199	256 (BufferedImage. 1 1 BufferedImage/TYPE_4BYTE_ABGR))
rlm@199	257 panel
rlm@199	258 (proxy [JPanel] []
rlm@199	259 (paint
rlm@199	260 [graphics]
rlm@199	261 (proxy-super paintComponent graphics)
rlm@199	262 (.drawImage graphics @image 0 0 nil)))
rlm@199	263 frame (JFrame. "Display Image")]
rlm@199	264 (SwingUtilities/invokeLater
rlm@199	265 (fn []
rlm@199	266 (doto frame
rlm@199	267 (-> (.getContentPane) (.add panel))
rlm@199	268 (.pack)
rlm@199	269 (.setLocationRelativeTo nil)
rlm@199	270 (.setResizable true)
rlm@199	271 (.setVisible true))))
rlm@199	272 (fn [#^BufferedImage i]
rlm@199	273 (reset! image i)
rlm@199	274 (.setSize frame (+ 8 (.getWidth i)) (+ 28 (.getHeight i)))
rlm@199	275 (.repaint panel 0 0 (.getWidth i) (.getHeight i))
rlm@199	276 (if save
rlm@199	277 (ImageIO/write
rlm@199	278 i "png"
rlm@199	279 (File. save (format "%07d.png" (swap! idx inc))))))))
rlm@199	280 ([] (view-image nil)))
rlm@199	281
rlm@199	282 (defn view-sense
rlm@199	283 "Take a kernel that produces a BufferedImage from some sense data
rlm@199	284 and return a function which takes a list of sense data, uses the
rlm@199	285 kernel to convert to images, and displays those images, each in
rlm@199	286 its own JFrame."
rlm@199	287 [sense-display-kernel]
rlm@199	288 (let [windows (atom [])]
rlm@215	289 (fn this
rlm@215	290 ([data]
rlm@215	291 (this data nil))
rlm@215	292 ([data save-to]
rlm@215	293 (if (> (count data) (count @windows))
rlm@215	294 (reset!
rlm@215	295 windows
rlm@215	296 (doall
rlm@215	297 (map
rlm@215	298 (fn [idx]
rlm@215	299 (if save-to
rlm@215	300 (let [dir (File. save-to (str idx))]
rlm@215	301 (.mkdir dir)
rlm@215	302 (view-image dir))
rlm@215	303 (view-image))) (range (count data))))))
rlm@215	304 (dorun
rlm@215	305 (map
rlm@215	306 (fn [display datum]
rlm@215	307 (display (sense-display-kernel datum)))
rlm@215	308 @windows data))))))
rlm@215	309
rlm@199	310
rlm@200	311 (defn points->image
rlm@306	312 "Take a collection of points and visualize it as a BufferedImage."
rlm@200	313 [points]
rlm@200	314 (if (empty? points)
rlm@200	315 (BufferedImage. 1 1 BufferedImage/TYPE_BYTE_BINARY)
rlm@200	316 (let [xs (vec (map first points))
rlm@200	317 ys (vec (map second points))
rlm@200	318 x0 (apply min xs)
rlm@200	319 y0 (apply min ys)
rlm@200	320 width (- (apply max xs) x0)
rlm@200	321 height (- (apply max ys) y0)
rlm@200	322 image (BufferedImage. (inc width) (inc height)
rlm@200	323 BufferedImage/TYPE_INT_RGB)]
rlm@200	324 (dorun
rlm@200	325 (for [x (range (.getWidth image))
rlm@200	326 y (range (.getHeight image))]
rlm@200	327 (.setRGB image x y 0xFF0000)))
rlm@200	328 (dorun
rlm@200	329 (for [index (range (count points))]
rlm@200	330 (.setRGB image (- (xs index) x0) (- (ys index) y0) -1)))
rlm@200	331 image)))
rlm@200	332
rlm@198	333 (defn gray
rlm@198	334 "Create a gray RGB pixel with R, G, and B set to num. num must be
rlm@198	335 between 0 and 255."
rlm@198	336 [num]
rlm@198	337 (+ num
rlm@198	338 (bit-shift-left num 8)
rlm@198	339 (bit-shift-left num 16)))
rlm@197	340 #+end_src
rlm@197	341
rlm@198	342 * Building a Sense from Nodes
rlm@198	343 My method for defining senses in blender is the following:
rlm@198	344
rlm@198	345 Senses like vision and hearing are localized to a single point
rlm@198	346 and follow a particular object around. For these:
rlm@198	347
rlm@198	348 - Create a single top-level empty node whose name is the name of the sense
rlm@198	349 - Add empty nodes which each contain meta-data relevant
rlm@198	350 to the sense, including a UV-map describing the number/distribution
rlm@306	351 of sensors if applicable.
rlm@198	352 - Make each empty-node the child of the top-level
rlm@273	353 node. =sense-nodes= below generates functions to find these children.
rlm@198	354
rlm@198	355 For touch, store the path to the UV-map which describes touch-sensors in the
rlm@198	356 meta-data of the object to which that map applies.
rlm@198	357
rlm@198	358 Each sense provides code that analyzes the Node structure of the
rlm@198	359 creature and creates sense-functions. They also modify the Node
rlm@198	360 structure if necessary.
rlm@198	361
rlm@198	362 Empty nodes created in blender have no appearance or physical presence
rlm@198	363 in jMonkeyEngine, but do appear in the scene graph. Empty nodes that
rlm@198	364 represent a sense which "follows" another geometry (like eyes and
rlm@273	365 ears) follow the closest physical object. =closest-node= finds this
rlm@198	366 closest object given the Creature and a particular empty node.
rlm@198	367
rlm@198	368 #+name: node-1
rlm@197	369 #+begin_src clojure
rlm@198	370 (defn sense-nodes
rlm@198	371 "For some senses there is a special empty blender node whose
rlm@198	372 children are considered markers for an instance of that sense. This
rlm@198	373 function generates functions to find those children, given the name
rlm@198	374 of the special parent node."
rlm@198	375 [parent-name]
rlm@198	376 (fn [#^Node creature]
rlm@198	377 (if-let [sense-node (.getChild creature parent-name)]
rlm@198	378 (seq (.getChildren sense-node))
rlm@198	379 (do (println-repl "could not find" parent-name "node") []))))
rlm@198	380
rlm@197	381 (defn closest-node
rlm@201	382 "Return the physical node in creature which is closest to the given
rlm@201	383 node."
rlm@198	384 [#^Node creature #^Node empty]
rlm@197	385 (loop [radius (float 0.01)]
rlm@197	386 (let [results (CollisionResults.)]
rlm@197	387 (.collideWith
rlm@197	388 creature
rlm@198	389 (BoundingBox. (.getWorldTranslation empty)
rlm@197	390 radius radius radius)
rlm@197	391 results)
rlm@197	392 (if-let [target (first results)]
rlm@197	393 (.getGeometry target)
rlm@197	394 (recur (float (* 2 radius)))))))
rlm@197	395
rlm@198	396 (defn world-to-local
rlm@198	397 "Convert the world coordinates into coordinates relative to the
rlm@198	398 object (i.e. local coordinates), taking into account the rotation
rlm@198	399 of object."
rlm@198	400 [#^Spatial object world-coordinate]
rlm@198	401 (.worldToLocal object world-coordinate nil))
rlm@198	402
rlm@198	403 (defn local-to-world
rlm@198	404 "Convert the local coordinates into world relative coordinates"
rlm@198	405 [#^Spatial object local-coordinate]
rlm@198	406 (.localToWorld object local-coordinate nil))
rlm@198	407 #+end_src
rlm@198	408
rlm@200	409 ** Sense Binding
rlm@200	410
rlm@273	411 =bind-sense= binds either a Camera or a Listener object to any
rlm@198	412 object so that they will follow that object no matter how it
rlm@199	413 moves. It is used to create both eyes and ears.
rlm@198	414
rlm@198	415 #+name: node-2
rlm@198	416 #+begin_src clojure
rlm@197	417 (defn bind-sense
rlm@197	418 "Bind the sense to the Spatial such that it will maintain its
rlm@197	419 current position relative to the Spatial no matter how the spatial
rlm@197	420 moves. 'sense can be either a Camera or Listener object."
rlm@197	421 [#^Spatial obj sense]
rlm@197	422 (let [sense-offset (.subtract (.getLocation sense)
rlm@197	423 (.getWorldTranslation obj))
rlm@197	424 initial-sense-rotation (Quaternion. (.getRotation sense))
rlm@197	425 base-anti-rotation (.inverse (.getWorldRotation obj))]
rlm@197	426 (.addControl
rlm@197	427 obj
rlm@197	428 (proxy [AbstractControl] []
rlm@197	429 (controlUpdate [tpf]
rlm@197	430 (let [total-rotation
rlm@197	431 (.mult base-anti-rotation (.getWorldRotation obj))]
rlm@197	432 (.setLocation
rlm@197	433 sense
rlm@197	434 (.add
rlm@197	435 (.mult total-rotation sense-offset)
rlm@197	436 (.getWorldTranslation obj)))
rlm@197	437 (.setRotation
rlm@197	438 sense
rlm@197	439 (.mult total-rotation initial-sense-rotation))))
rlm@197	440 (controlRender [_ _])))))
rlm@197	441 #+end_src
rlm@164	442
rlm@200	443 Here is some example code which shows how a camera bound to a blue box
rlm@273	444 with =bind-sense= moves as the box is buffeted by white cannonballs.
rlm@199	445
rlm@199	446 #+name: test
rlm@199	447 #+begin_src clojure
rlm@199	448 (defn test-bind-sense
rlm@201	449 "Show a camera that stays in the same relative position to a blue
rlm@201	450 cube."
rlm@283	451 ([] (test-bind-sense false))
rlm@283	452 ([record?]
rlm@283	453 (let [eye-pos (Vector3f. 0 30 0)
rlm@283	454 rock (box 1 1 1 :color ColorRGBA/Blue
rlm@283	455 :position (Vector3f. 0 10 0)
rlm@283	456 :mass 30)
rlm@283	457 table (box 3 1 10 :color ColorRGBA/Gray :mass 0
rlm@283	458 :position (Vector3f. 0 -3 0))]
rlm@283	459 (world
rlm@283	460 (nodify [rock table])
rlm@283	461 standard-debug-controls
rlm@283	462 (fn init [world]
rlm@283	463 (let [cam (doto (.clone (.getCamera world))
rlm@283	464 (.setLocation eye-pos)
rlm@283	465 (.lookAt Vector3f/ZERO
rlm@283	466 Vector3f/UNIT_X))]
rlm@283	467 (bind-sense rock cam)
rlm@283	468 (.setTimer world (RatchetTimer. 60))
rlm@283	469 (if record?
rlm@283	470 (Capture/captureVideo
rlm@283	471 world (File. "/home/r/proj/cortex/render/bind-sense0")))
rlm@283	472 (add-camera!
rlm@283	473 world cam
rlm@283	474 (comp (view-image
rlm@283	475 (if record?
rlm@283	476 (File. "/home/r/proj/cortex/render/bind-sense1")))
rlm@283	477 BufferedImage!))
rlm@283	478 (add-camera! world (.getCamera world) no-op)))
rlm@283	479 no-op))))
rlm@199	480 #+end_src
rlm@199	481
rlm@199	482 #+begin_html
rlm@199	483 <video controls="controls" width="755">
rlm@199	484 <source src="../video/bind-sense.ogg" type="video/ogg"
rlm@199	485 preload="none" poster="../images/aurellem-1280x480.png" />
rlm@199	486 </video>
rlm@309	487 <br> <a href="http://youtu.be/DvoN2wWQ_6o"> YouTube </a>
rlm@199	488 #+end_html
rlm@199	489
rlm@200	490 With this, eyes are easy --- you just bind the camera closer to the
rlm@200	491 desired object, and set it to look outward instead of inward as it
rlm@200	492 does in the video.
rlm@199	493
rlm@200	494 (nb : the video was created with the following commands)
rlm@199	495
rlm@200	496 *** Combine Frames with ImageMagick
rlm@199	497 #+begin_src clojure :results silent
rlm@215	498 (ns cortex.video.magick
rlm@215	499 (:import java.io.File)
rlm@215	500 (:use clojure.contrib.shell-out))
rlm@215	501
rlm@215	502 (defn combine-images []
rlm@215	503 (let
rlm@215	504 [idx (atom -1)
rlm@215	505 left (rest
rlm@215	506 (sort
rlm@215	507 (file-seq (File. "/home/r/proj/cortex/render/bind-sense0/"))))
rlm@215	508 right (rest
rlm@215	509 (sort
rlm@215	510 (file-seq
rlm@215	511 (File. "/home/r/proj/cortex/render/bind-sense1/"))))
rlm@215	512 sub (rest
rlm@199	513 (sort
rlm@200	514 (file-seq
rlm@215	515 (File. "/home/r/proj/cortex/render/bind-senseB/"))))
rlm@215	516 sub* (concat sub (repeat 1000 (last sub)))]
rlm@215	517 (dorun
rlm@215	518 (map
rlm@215	519 (fn [im-1 im-2 sub]
rlm@215	520 (sh "convert" (.getCanonicalPath im-1)
rlm@215	521 (.getCanonicalPath im-2) "+append"
rlm@215	522 (.getCanonicalPath sub) "-append"
rlm@215	523 (.getCanonicalPath
rlm@215	524 (File. "/home/r/proj/cortex/render/bind-sense/"
rlm@215	525 (format "%07d.png" (swap! idx inc))))))
rlm@215	526 left right sub*))))
rlm@199	527 #+end_src
rlm@199	528
rlm@200	529 *** Encode Frames with ffmpeg
rlm@200	530
rlm@199	531 #+begin_src sh :results silent
rlm@199	532 cd /home/r/proj/cortex/render/
rlm@221	533 ffmpeg -r 30 -i bind-sense/%07d.png -b:v 9000k -vcodec libtheora bind-sense.ogg
rlm@199	534 #+end_src
rlm@199	535
rlm@211	536 * Headers
rlm@211	537 #+name: sense-header
rlm@197	538 #+begin_src clojure
rlm@198	539 (ns cortex.sense
rlm@198	540 "Here are functions useful in the construction of two or more
rlm@198	541 sensors/effectors."
rlm@306	542 {:author "Robert McIntyre"}
rlm@198	543 (:use (cortex world util))
rlm@198	544 (:import ij.process.ImageProcessor)
rlm@198	545 (:import jme3tools.converters.ImageToAwt)
rlm@198	546 (:import java.awt.image.BufferedImage)
rlm@198	547 (:import com.jme3.collision.CollisionResults)
rlm@198	548 (:import com.jme3.bounding.BoundingBox)
rlm@198	549 (:import (com.jme3.scene Node Spatial))
rlm@198	550 (:import com.jme3.scene.control.AbstractControl)
rlm@199	551 (:import (com.jme3.math Quaternion Vector3f))
rlm@199	552 (:import javax.imageio.ImageIO)
rlm@199	553 (:import java.io.File)
rlm@199	554 (:import (javax.swing JPanel JFrame SwingUtilities)))
rlm@198	555 #+end_src
rlm@187	556
rlm@211	557 #+name: test-header
rlm@211	558 #+begin_src clojure
rlm@211	559 (ns cortex.test.sense
rlm@211	560 (:use (cortex world util sense vision))
rlm@211	561 (:import
rlm@211	562 java.io.File
rlm@211	563 (com.jme3.math Vector3f ColorRGBA)
rlm@211	564 (com.aurellem.capture RatchetTimer Capture)))
rlm@211	565 #+end_src
rlm@211	566
rlm@198	567 * Source Listing
rlm@211	568 - [[../src/cortex/sense.clj][cortex.sense]]
rlm@211	569 - [[../src/cortex/test/sense.clj][cortex.test.sense]]
rlm@211	570 - [[../assets/Models/subtitles/subtitles.blend][subtitles.blend]]
rlm@211	571 - [[../assets/Models/subtitles/Lake_CraterLake03_sm.hdr][subtitles reflection map]]
rlm@211	572 #+html: <ul> <li> <a href="../org/sense.org">This org file</a> </li> </ul>
rlm@217	573 - [[http://hg.bortreb.com ][source-repository]]
rlm@211	574
rlm@211	575 * Next
rlm@211	576 Now that some of the preliminaries are out of the way, in the [[./body.org][next
rlm@211	577 post]] I'll create a simulated body.
rlm@198	578
rlm@187	579
rlm@151	580 * COMMENT generate source
rlm@151	581 #+begin_src clojure :tangle ../src/cortex/sense.clj
rlm@211	582 <<sense-header>>
rlm@198	583 <<blender-1>>
rlm@198	584 <<blender-2>>
rlm@198	585 <<topology-1>>
rlm@198	586 <<topology-2>>
rlm@198	587 <<node-1>>
rlm@198	588 <<node-2>>
rlm@197	589 <<view-senses>>
rlm@151	590 #+end_src
rlm@199	591
rlm@199	592 #+begin_src clojure :tangle ../src/cortex/test/sense.clj
rlm@211	593 <<test-header>>
rlm@199	594 <<test>>
rlm@199	595 #+end_src
rlm@215	596
rlm@215	597 #+begin_src clojure :tangle ../src/cortex/video/magick.clj
rlm@215	598 <<magick>>
rlm@215	599 #+end_src

Mercurial > cortex

annotate org/sense.org @ 309:5d448182c807