cortex: thesis/cortex.org annotate

annotate thesis/cortex.org @ 451:0a4362d1f138

finishing up chapter 3.

author	Robert McIntyre <rlm@mit.edu>
date	Wed, 26 Mar 2014 20:38:17 -0400
parents	432f2c4646cb
children	f339e3d5cc8c

rev	line source
rlm@425	1 #+title: =CORTEX=
rlm@425	2 #+author: Robert McIntyre
rlm@425	3 #+email: rlm@mit.edu
rlm@425	4 #+description: Using embodied AI to facilitate Artificial Imagination.
rlm@425	5 #+keywords: AI, clojure, embodiment
rlm@451	6 #+LaTeX_CLASS_OPTIONS: [nofloat]
rlm@422	7
rlm@451	8 * Empathy and Embodiment as problem solving strategieszzzzzzz
rlm@437	9
rlm@437	10 By the end of this thesis, you will have seen a novel approach to
rlm@437	11 interpreting video using embodiment and empathy. You will have also
rlm@437	12 seen one way to efficiently implement empathy for embodied
rlm@447	13 creatures. Finally, you will become familiar with =CORTEX=, a system
rlm@447	14 for designing and simulating creatures with rich senses, which you
rlm@447	15 may choose to use in your own research.
rlm@437	16
rlm@441	17 This is the core vision of my thesis: That one of the important ways
rlm@441	18 in which we understand others is by imagining ourselves in their
rlm@441	19 position and emphatically feeling experiences relative to our own
rlm@441	20 bodies. By understanding events in terms of our own previous
rlm@441	21 corporeal experience, we greatly constrain the possibilities of what
rlm@441	22 would otherwise be an unwieldy exponential search. This extra
rlm@441	23 constraint can be the difference between easily understanding what
rlm@441	24 is happening in a video and being completely lost in a sea of
rlm@441	25 incomprehensible color and movement.
rlm@435	26
rlm@436	27 ** Recognizing actions in video is extremely difficult
rlm@437	28
rlm@447	29 Consider for example the problem of determining what is happening
rlm@447	30 in a video of which this is one frame:
rlm@437	31
rlm@441	32 #+caption: A cat drinking some water. Identifying this action is
rlm@441	33 #+caption: beyond the state of the art for computers.
rlm@441	34 #+ATTR_LaTeX: :width 7cm
rlm@441	35 [[./images/cat-drinking.jpg]]
rlm@441	36
rlm@441	37 It is currently impossible for any computer program to reliably
rlm@447	38 label such a video as ``drinking''. And rightly so -- it is a very
rlm@441	39 hard problem! What features can you describe in terms of low level
rlm@441	40 functions of pixels that can even begin to describe at a high level
rlm@441	41 what is happening here?
rlm@437	42
rlm@447	43 Or suppose that you are building a program that recognizes chairs.
rlm@448	44 How could you ``see'' the chair in figure \ref{hidden-chair}?
rlm@441	45
rlm@441	46 #+caption: The chair in this image is quite obvious to humans, but I
rlm@448	47 #+caption: doubt that any modern computer vision program can find it.
rlm@441	48 #+name: hidden-chair
rlm@441	49 #+ATTR_LaTeX: :width 10cm
rlm@441	50 [[./images/fat-person-sitting-at-desk.jpg]]
rlm@441	51
rlm@441	52 Finally, how is it that you can easily tell the difference between
rlm@441	53 how the girls /muscles/ are working in figure \ref{girl}?
rlm@441	54
rlm@441	55 #+caption: The mysterious ``common sense'' appears here as you are able
rlm@441	56 #+caption: to discern the difference in how the girl's arm muscles
rlm@441	57 #+caption: are activated between the two images.
rlm@441	58 #+name: girl
rlm@448	59 #+ATTR_LaTeX: :width 7cm
rlm@441	60 [[./images/wall-push.png]]
rlm@437	61
rlm@441	62 Each of these examples tells us something about what might be going
rlm@441	63 on in our minds as we easily solve these recognition problems.
rlm@441	64
rlm@441	65 The hidden chairs show us that we are strongly triggered by cues
rlm@447	66 relating to the position of human bodies, and that we can determine
rlm@447	67 the overall physical configuration of a human body even if much of
rlm@447	68 that body is occluded.
rlm@437	69
rlm@441	70 The picture of the girl pushing against the wall tells us that we
rlm@441	71 have common sense knowledge about the kinetics of our own bodies.
rlm@441	72 We know well how our muscles would have to work to maintain us in
rlm@441	73 most positions, and we can easily project this self-knowledge to
rlm@441	74 imagined positions triggered by images of the human body.
rlm@441	75
rlm@441	76 ** =EMPATH= neatly solves recognition problems
rlm@441	77
rlm@441	78 I propose a system that can express the types of recognition
rlm@441	79 problems above in a form amenable to computation. It is split into
rlm@441	80 four parts:
rlm@441	81
rlm@448	82 - Free/Guided Play :: The creature moves around and experiences the
rlm@448	83 world through its unique perspective. Many otherwise
rlm@448	84 complicated actions are easily described in the language of a
rlm@448	85 full suite of body-centered, rich senses. For example,
rlm@448	86 drinking is the feeling of water sliding down your throat, and
rlm@448	87 cooling your insides. It's often accompanied by bringing your
rlm@448	88 hand close to your face, or bringing your face close to water.
rlm@448	89 Sitting down is the feeling of bending your knees, activating
rlm@448	90 your quadriceps, then feeling a surface with your bottom and
rlm@448	91 relaxing your legs. These body-centered action descriptions
rlm@448	92 can be either learned or hard coded.
rlm@448	93 - Posture Imitation :: When trying to interpret a video or image,
rlm@448	94 the creature takes a model of itself and aligns it with
rlm@448	95 whatever it sees. This alignment can even cross species, as
rlm@448	96 when humans try to align themselves with things like ponies,
rlm@448	97 dogs, or other humans with a different body type.
rlm@448	98 - Empathy :: The alignment triggers associations with
rlm@448	99 sensory data from prior experiences. For example, the
rlm@448	100 alignment itself easily maps to proprioceptive data. Any
rlm@448	101 sounds or obvious skin contact in the video can to a lesser
rlm@448	102 extent trigger previous experience. Segments of previous
rlm@448	103 experiences are stitched together to form a coherent and
rlm@448	104 complete sensory portrait of the scene.
rlm@448	105 - Recognition :: With the scene described in terms of first
rlm@448	106 person sensory events, the creature can now run its
rlm@447	107 action-identification programs on this synthesized sensory
rlm@447	108 data, just as it would if it were actually experiencing the
rlm@447	109 scene first-hand. If previous experience has been accurately
rlm@447	110 retrieved, and if it is analogous enough to the scene, then
rlm@447	111 the creature will correctly identify the action in the scene.
rlm@447	112
rlm@441	113 For example, I think humans are able to label the cat video as
rlm@447	114 ``drinking'' because they imagine /themselves/ as the cat, and
rlm@441	115 imagine putting their face up against a stream of water and
rlm@441	116 sticking out their tongue. In that imagined world, they can feel
rlm@441	117 the cool water hitting their tongue, and feel the water entering
rlm@447	118 their body, and are able to recognize that /feeling/ as drinking.
rlm@447	119 So, the label of the action is not really in the pixels of the
rlm@447	120 image, but is found clearly in a simulation inspired by those
rlm@447	121 pixels. An imaginative system, having been trained on drinking and
rlm@447	122 non-drinking examples and learning that the most important
rlm@447	123 component of drinking is the feeling of water sliding down one's
rlm@447	124 throat, would analyze a video of a cat drinking in the following
rlm@447	125 manner:
rlm@441	126
rlm@447	127 1. Create a physical model of the video by putting a ``fuzzy''
rlm@447	128 model of its own body in place of the cat. Possibly also create
rlm@447	129 a simulation of the stream of water.
rlm@441	130
rlm@441	131 2. Play out this simulated scene and generate imagined sensory
rlm@441	132 experience. This will include relevant muscle contractions, a
rlm@441	133 close up view of the stream from the cat's perspective, and most
rlm@441	134 importantly, the imagined feeling of water entering the
rlm@443	135 mouth. The imagined sensory experience can come from a
rlm@441	136 simulation of the event, but can also be pattern-matched from
rlm@441	137 previous, similar embodied experience.
rlm@441	138
rlm@441	139 3. The action is now easily identified as drinking by the sense of
rlm@441	140 taste alone. The other senses (such as the tongue moving in and
rlm@441	141 out) help to give plausibility to the simulated action. Note that
rlm@441	142 the sense of vision, while critical in creating the simulation,
rlm@441	143 is not critical for identifying the action from the simulation.
rlm@441	144
rlm@441	145 For the chair examples, the process is even easier:
rlm@441	146
rlm@441	147 1. Align a model of your body to the person in the image.
rlm@441	148
rlm@441	149 2. Generate proprioceptive sensory data from this alignment.
rlm@437	150
rlm@441	151 3. Use the imagined proprioceptive data as a key to lookup related
rlm@441	152 sensory experience associated with that particular proproceptive
rlm@441	153 feeling.
rlm@437	154
rlm@443	155 4. Retrieve the feeling of your bottom resting on a surface, your
rlm@443	156 knees bent, and your leg muscles relaxed.
rlm@437	157
rlm@441	158 5. This sensory information is consistent with the =sitting?=
rlm@441	159 sensory predicate, so you (and the entity in the image) must be
rlm@441	160 sitting.
rlm@440	161
rlm@441	162 6. There must be a chair-like object since you are sitting.
rlm@440	163
rlm@441	164 Empathy offers yet another alternative to the age-old AI
rlm@441	165 representation question: ``What is a chair?'' --- A chair is the
rlm@441	166 feeling of sitting.
rlm@441	167
rlm@441	168 My program, =EMPATH= uses this empathic problem solving technique
rlm@441	169 to interpret the actions of a simple, worm-like creature.
rlm@437	170
rlm@441	171 #+caption: The worm performs many actions during free play such as
rlm@441	172 #+caption: curling, wiggling, and resting.
rlm@441	173 #+name: worm-intro
rlm@446	174 #+ATTR_LaTeX: :width 15cm
rlm@445	175 [[./images/worm-intro-white.png]]
rlm@437	176
rlm@447	177 #+caption: =EMPATH= recognized and classified each of these poses by
rlm@447	178 #+caption: inferring the complete sensory experience from
rlm@447	179 #+caption: proprioceptive data.
rlm@441	180 #+name: worm-recognition-intro
rlm@446	181 #+ATTR_LaTeX: :width 15cm
rlm@445	182 [[./images/worm-poses.png]]
rlm@441	183
rlm@441	184 One powerful advantage of empathic problem solving is that it
rlm@441	185 factors the action recognition problem into two easier problems. To
rlm@441	186 use empathy, you need an /aligner/, which takes the video and a
rlm@441	187 model of your body, and aligns the model with the video. Then, you
rlm@441	188 need a /recognizer/, which uses the aligned model to interpret the
rlm@441	189 action. The power in this method lies in the fact that you describe
rlm@448	190 all actions form a body-centered viewpoint. You are less tied to
rlm@447	191 the particulars of any visual representation of the actions. If you
rlm@441	192 teach the system what ``running'' is, and you have a good enough
rlm@441	193 aligner, the system will from then on be able to recognize running
rlm@441	194 from any point of view, even strange points of view like above or
rlm@441	195 underneath the runner. This is in contrast to action recognition
rlm@448	196 schemes that try to identify actions using a non-embodied approach.
rlm@448	197 If these systems learn about running as viewed from the side, they
rlm@448	198 will not automatically be able to recognize running from any other
rlm@448	199 viewpoint.
rlm@441	200
rlm@441	201 Another powerful advantage is that using the language of multiple
rlm@441	202 body-centered rich senses to describe body-centerd actions offers a
rlm@441	203 massive boost in descriptive capability. Consider how difficult it
rlm@441	204 would be to compose a set of HOG filters to describe the action of
rlm@447	205 a simple worm-creature ``curling'' so that its head touches its
rlm@447	206 tail, and then behold the simplicity of describing thus action in a
rlm@441	207 language designed for the task (listing \ref{grand-circle-intro}):
rlm@441	208
rlm@446	209 #+caption: Body-centerd actions are best expressed in a body-centered
rlm@446	210 #+caption: language. This code detects when the worm has curled into a
rlm@446	211 #+caption: full circle. Imagine how you would replicate this functionality
rlm@446	212 #+caption: using low-level pixel features such as HOG filters!
rlm@446	213 #+name: grand-circle-intro
rlm@446	214 #+begin_listing clojure
rlm@446	215 #+begin_src clojure
rlm@446	216 (defn grand-circle?
rlm@446	217 "Does the worm form a majestic circle (one end touching the other)?"
rlm@446	218 [experiences]
rlm@446	219 (and (curled? experiences)
rlm@446	220 (let [worm-touch (:touch (peek experiences))
rlm@446	221 tail-touch (worm-touch 0)
rlm@446	222 head-touch (worm-touch 4)]
rlm@446	223 (and (< 0.55 (contact worm-segment-bottom-tip tail-touch))
rlm@446	224 (< 0.55 (contact worm-segment-top-tip head-touch))))))
rlm@446	225 #+end_src
rlm@446	226 #+end_listing
rlm@446	227
rlm@435	228
rlm@449	229 ** =CORTEX= is a toolkit for building sensate creatures
rlm@435	230
rlm@448	231 I built =CORTEX= to be a general AI research platform for doing
rlm@448	232 experiments involving multiple rich senses and a wide variety and
rlm@448	233 number of creatures. I intend it to be useful as a library for many
rlm@448	234 more projects than just this one. =CORTEX= was necessary to meet a
rlm@448	235 need among AI researchers at CSAIL and beyond, which is that people
rlm@448	236 often will invent neat ideas that are best expressed in the
rlm@448	237 language of creatures and senses, but in order to explore those
rlm@448	238 ideas they must first build a platform in which they can create
rlm@448	239 simulated creatures with rich senses! There are many ideas that
rlm@448	240 would be simple to execute (such as =EMPATH=), but attached to them
rlm@448	241 is the multi-month effort to make a good creature simulator. Often,
rlm@448	242 that initial investment of time proves to be too much, and the
rlm@448	243 project must make do with a lesser environment.
rlm@435	244
rlm@448	245 =CORTEX= is well suited as an environment for embodied AI research
rlm@448	246 for three reasons:
rlm@448	247
rlm@448	248 - You can create new creatures using Blender, a popular 3D modeling
rlm@448	249 program. Each sense can be specified using special blender nodes
rlm@448	250 with biologically inspired paramaters. You need not write any
rlm@448	251 code to create a creature, and can use a wide library of
rlm@448	252 pre-existing blender models as a base for your own creatures.
rlm@448	253
rlm@448	254 - =CORTEX= implements a wide variety of senses, including touch,
rlm@448	255 proprioception, vision, hearing, and muscle tension. Complicated
rlm@448	256 senses like touch, and vision involve multiple sensory elements
rlm@448	257 embedded in a 2D surface. You have complete control over the
rlm@448	258 distribution of these sensor elements through the use of simple
rlm@448	259 png image files. In particular, =CORTEX= implements more
rlm@448	260 comprehensive hearing than any other creature simulation system
rlm@448	261 available.
rlm@448	262
rlm@448	263 - =CORTEX= supports any number of creatures and any number of
rlm@448	264 senses. Time in =CORTEX= dialates so that the simulated creatures
rlm@448	265 always precieve a perfectly smooth flow of time, regardless of
rlm@448	266 the actual computational load.
rlm@448	267
rlm@448	268 =CORTEX= is built on top of =jMonkeyEngine3=, which is a video game
rlm@448	269 engine designed to create cross-platform 3D desktop games. =CORTEX=
rlm@448	270 is mainly written in clojure, a dialect of =LISP= that runs on the
rlm@448	271 java virtual machine (JVM). The API for creating and simulating
rlm@449	272 creatures and senses is entirely expressed in clojure, though many
rlm@449	273 senses are implemented at the layer of jMonkeyEngine or below. For
rlm@449	274 example, for the sense of hearing I use a layer of clojure code on
rlm@449	275 top of a layer of java JNI bindings that drive a layer of =C++=
rlm@449	276 code which implements a modified version of =OpenAL= to support
rlm@449	277 multiple listeners. =CORTEX= is the only simulation environment
rlm@449	278 that I know of that can support multiple entities that can each
rlm@449	279 hear the world from their own perspective. Other senses also
rlm@449	280 require a small layer of Java code. =CORTEX= also uses =bullet=, a
rlm@449	281 physics simulator written in =C=.
rlm@448	282
rlm@448	283 #+caption: Here is the worm from above modeled in Blender, a free
rlm@448	284 #+caption: 3D-modeling program. Senses and joints are described
rlm@448	285 #+caption: using special nodes in Blender.
rlm@448	286 #+name: worm-recognition-intro
rlm@448	287 #+ATTR_LaTeX: :width 12cm
rlm@448	288 [[./images/blender-worm.png]]
rlm@448	289
rlm@449	290 Here are some thing I anticipate that =CORTEX= might be used for:
rlm@449	291
rlm@449	292 - exploring new ideas about sensory integration
rlm@449	293 - distributed communication among swarm creatures
rlm@449	294 - self-learning using free exploration,
rlm@449	295 - evolutionary algorithms involving creature construction
rlm@449	296 - exploration of exoitic senses and effectors that are not possible
rlm@449	297 in the real world (such as telekenisis or a semantic sense)
rlm@449	298 - imagination using subworlds
rlm@449	299
rlm@451	300 During one test with =CORTEX=, I created 3,000 creatures each with
rlm@448	301 their own independent senses and ran them all at only 1/80 real
rlm@448	302 time. In another test, I created a detailed model of my own hand,
rlm@448	303 equipped with a realistic distribution of touch (more sensitive at
rlm@448	304 the fingertips), as well as eyes and ears, and it ran at around 1/4
rlm@451	305 real time.
rlm@448	306
rlm@451	307 #+BEGIN_LaTeX
rlm@449	308 \begin{sidewaysfigure}
rlm@449	309 \includegraphics[width=9.5in]{images/full-hand.png}
rlm@451	310 \caption{
rlm@451	311 I modeled my own right hand in Blender and rigged it with all the
rlm@451	312 senses that {\tt CORTEX} supports. My simulated hand has a
rlm@451	313 biologically inspired distribution of touch sensors. The senses are
rlm@451	314 displayed on the right, and the simulation is displayed on the
rlm@451	315 left. Notice that my hand is curling its fingers, that it can see
rlm@451	316 its own finger from the eye in its palm, and that it can feel its
rlm@451	317 own thumb touching its palm.}
rlm@449	318 \end{sidewaysfigure}
rlm@451	319 #+END_LaTeX
rlm@448	320
rlm@437	321 ** Contributions
rlm@435	322
rlm@451	323 - I built =CORTEX=, a comprehensive platform for embodied AI
rlm@451	324 experiments. =CORTEX= supports many features lacking in other
rlm@451	325 systems, such proper simulation of hearing. It is easy to create
rlm@451	326 new =CORTEX= creatures using Blender, a free 3D modeling program.
rlm@449	327
rlm@451	328 - I built =EMPATH=, which uses =CORTEX= to identify the actions of
rlm@451	329 a worm-like creature using a computational model of empathy.
rlm@449	330
rlm@436	331 * Building =CORTEX=
rlm@435	332
rlm@436	333 ** To explore embodiment, we need a world, body, and senses
rlm@435	334
rlm@436	335 ** Because of Time, simulation is perferable to reality
rlm@435	336
rlm@436	337 ** Video game engines are a great starting point
rlm@435	338
rlm@436	339 ** Bodies are composed of segments connected by joints
rlm@435	340
rlm@436	341 ** Eyes reuse standard video game components
rlm@436	342
rlm@436	343 ** Hearing is hard; =CORTEX= does it right
rlm@436	344
rlm@436	345 ** Touch uses hundreds of hair-like elements
rlm@436	346
rlm@440	347 ** Proprioception is the sense that makes everything ``real''
rlm@436	348
rlm@436	349 ** Muscles are both effectors and sensors
rlm@436	350
rlm@436	351 ** =CORTEX= brings complex creatures to life!
rlm@436	352
rlm@436	353 ** =CORTEX= enables many possiblities for further research
rlm@435	354
rlm@435	355 * Empathy in a simulated worm
rlm@435	356
rlm@449	357 Here I develop a computational model of empathy, using =CORTEX= as a
rlm@449	358 base. Empathy in this context is the ability to observe another
rlm@449	359 creature and infer what sorts of sensations that creature is
rlm@449	360 feeling. My empathy algorithm involves multiple phases. First is
rlm@449	361 free-play, where the creature moves around and gains sensory
rlm@449	362 experience. From this experience I construct a representation of the
rlm@449	363 creature's sensory state space, which I call \Phi-space. Using
rlm@449	364 \Phi-space, I construct an efficient function which takes the
rlm@449	365 limited data that comes from observing another creature and enriches
rlm@449	366 it full compliment of imagined sensory data. I can then use the
rlm@449	367 imagined sensory data to recognize what the observed creature is
rlm@449	368 doing and feeling, using straightforward embodied action predicates.
rlm@449	369 This is all demonstrated with using a simple worm-like creature, and
rlm@449	370 recognizing worm-actions based on limited data.
rlm@449	371
rlm@449	372 #+caption: Here is the worm with which we will be working.
rlm@449	373 #+caption: It is composed of 5 segments. Each segment has a
rlm@449	374 #+caption: pair of extensor and flexor muscles. Each of the
rlm@449	375 #+caption: worm's four joints is a hinge joint which allows
rlm@451	376 #+caption: about 30 degrees of rotation to either side. Each segment
rlm@449	377 #+caption: of the worm is touch-capable and has a uniform
rlm@449	378 #+caption: distribution of touch sensors on each of its faces.
rlm@449	379 #+caption: Each joint has a proprioceptive sense to detect
rlm@449	380 #+caption: relative positions. The worm segments are all the
rlm@449	381 #+caption: same except for the first one, which has a much
rlm@449	382 #+caption: higher weight than the others to allow for easy
rlm@449	383 #+caption: manual motor control.
rlm@449	384 #+name: basic-worm-view
rlm@449	385 #+ATTR_LaTeX: :width 10cm
rlm@449	386 [[./images/basic-worm-view.png]]
rlm@449	387
rlm@449	388 #+caption: Program for reading a worm from a blender file and
rlm@449	389 #+caption: outfitting it with the senses of proprioception,
rlm@449	390 #+caption: touch, and the ability to move, as specified in the
rlm@449	391 #+caption: blender file.
rlm@449	392 #+name: get-worm
rlm@449	393 #+begin_listing clojure
rlm@449	394 #+begin_src clojure
rlm@449	395 (defn worm []
rlm@449	396 (let [model (load-blender-model "Models/worm/worm.blend")]
rlm@449	397 {:body (doto model (body!))
rlm@449	398 :touch (touch! model)
rlm@449	399 :proprioception (proprioception! model)
rlm@449	400 :muscles (movement! model)}))
rlm@449	401 #+end_src
rlm@449	402 #+end_listing
rlm@449	403
rlm@436	404 ** Embodiment factors action recognition into managable parts
rlm@435	405
rlm@449	406 Using empathy, I divide the problem of action recognition into a
rlm@449	407 recognition process expressed in the language of a full compliment
rlm@449	408 of senses, and an imaganitive process that generates full sensory
rlm@449	409 data from partial sensory data. Splitting the action recognition
rlm@449	410 problem in this manner greatly reduces the total amount of work to
rlm@449	411 recognize actions: The imaganitive process is mostly just matching
rlm@449	412 previous experience, and the recognition process gets to use all
rlm@449	413 the senses to directly describe any action.
rlm@449	414
rlm@436	415 ** Action recognition is easy with a full gamut of senses
rlm@435	416
rlm@449	417 Embodied representations using multiple senses such as touch,
rlm@449	418 proprioception, and muscle tension turns out be be exceedingly
rlm@449	419 efficient at describing body-centered actions. It is the ``right
rlm@449	420 language for the job''. For example, it takes only around 5 lines
rlm@449	421 of LISP code to describe the action of ``curling'' using embodied
rlm@451	422 primitives. It takes about 10 lines to describe the seemingly
rlm@449	423 complicated action of wiggling.
rlm@449	424
rlm@449	425 The following action predicates each take a stream of sensory
rlm@449	426 experience, observe however much of it they desire, and decide
rlm@449	427 whether the worm is doing the action they describe. =curled?=
rlm@449	428 relies on proprioception, =resting?= relies on touch, =wiggling?=
rlm@449	429 relies on a fourier analysis of muscle contraction, and
rlm@449	430 =grand-circle?= relies on touch and reuses =curled?= as a gaurd.
rlm@449	431
rlm@449	432 #+caption: Program for detecting whether the worm is curled. This is the
rlm@449	433 #+caption: simplest action predicate, because it only uses the last frame
rlm@449	434 #+caption: of sensory experience, and only uses proprioceptive data. Even
rlm@449	435 #+caption: this simple predicate, however, is automatically frame
rlm@449	436 #+caption: independent and ignores vermopomorphic differences such as
rlm@449	437 #+caption: worm textures and colors.
rlm@449	438 #+name: curled
rlm@449	439 #+begin_listing clojure
rlm@449	440 #+begin_src clojure
rlm@449	441 (defn curled?
rlm@449	442 "Is the worm curled up?"
rlm@449	443 [experiences]
rlm@449	444 (every?
rlm@449	445 (fn [[_ _ bend]]
rlm@449	446 (> (Math/sin bend) 0.64))
rlm@449	447 (:proprioception (peek experiences))))
rlm@449	448 #+end_src
rlm@449	449 #+end_listing
rlm@449	450
rlm@449	451 #+caption: Program for summarizing the touch information in a patch
rlm@449	452 #+caption: of skin.
rlm@449	453 #+name: touch-summary
rlm@449	454 #+begin_listing clojure
rlm@449	455 #+begin_src clojure
rlm@449	456 (defn contact
rlm@449	457 "Determine how much contact a particular worm segment has with
rlm@449	458 other objects. Returns a value between 0 and 1, where 1 is full
rlm@449	459 contact and 0 is no contact."
rlm@449	460 [touch-region [coords contact :as touch]]
rlm@449	461 (-> (zipmap coords contact)
rlm@449	462 (select-keys touch-region)
rlm@449	463 (vals)
rlm@449	464 (#(map first %))
rlm@449	465 (average)
rlm@449	466 (* 10)
rlm@449	467 (- 1)
rlm@449	468 (Math/abs)))
rlm@449	469 #+end_src
rlm@449	470 #+end_listing
rlm@449	471
rlm@449	472
rlm@449	473 #+caption: Program for detecting whether the worm is at rest. This program
rlm@449	474 #+caption: uses a summary of the tactile information from the underbelly
rlm@449	475 #+caption: of the worm, and is only true if every segment is touching the
rlm@449	476 #+caption: floor. Note that this function contains no references to
rlm@449	477 #+caption: proprioction at all.
rlm@449	478 #+name: resting
rlm@449	479 #+begin_listing clojure
rlm@449	480 #+begin_src clojure
rlm@449	481 (def worm-segment-bottom (rect-region [8 15] [14 22]))
rlm@449	482
rlm@449	483 (defn resting?
rlm@449	484 "Is the worm resting on the ground?"
rlm@449	485 [experiences]
rlm@449	486 (every?
rlm@449	487 (fn [touch-data]
rlm@449	488 (< 0.9 (contact worm-segment-bottom touch-data)))
rlm@449	489 (:touch (peek experiences))))
rlm@449	490 #+end_src
rlm@449	491 #+end_listing
rlm@449	492
rlm@449	493 #+caption: Program for detecting whether the worm is curled up into a
rlm@449	494 #+caption: full circle. Here the embodied approach begins to shine, as
rlm@449	495 #+caption: I am able to both use a previous action predicate (=curled?=)
rlm@449	496 #+caption: as well as the direct tactile experience of the head and tail.
rlm@449	497 #+name: grand-circle
rlm@449	498 #+begin_listing clojure
rlm@449	499 #+begin_src clojure
rlm@449	500 (def worm-segment-bottom-tip (rect-region [15 15] [22 22]))
rlm@449	501
rlm@449	502 (def worm-segment-top-tip (rect-region [0 15] [7 22]))
rlm@449	503
rlm@449	504 (defn grand-circle?
rlm@449	505 "Does the worm form a majestic circle (one end touching the other)?"
rlm@449	506 [experiences]
rlm@449	507 (and (curled? experiences)
rlm@449	508 (let [worm-touch (:touch (peek experiences))
rlm@449	509 tail-touch (worm-touch 0)
rlm@449	510 head-touch (worm-touch 4)]
rlm@449	511 (and (< 0.55 (contact worm-segment-bottom-tip tail-touch))
rlm@449	512 (< 0.55 (contact worm-segment-top-tip head-touch))))))
rlm@449	513 #+end_src
rlm@449	514 #+end_listing
rlm@449	515
rlm@449	516
rlm@449	517 #+caption: Program for detecting whether the worm has been wiggling for
rlm@449	518 #+caption: the last few frames. It uses a fourier analysis of the muscle
rlm@449	519 #+caption: contractions of the worm's tail to determine wiggling. This is
rlm@449	520 #+caption: signigicant because there is no particular frame that clearly
rlm@449	521 #+caption: indicates that the worm is wiggling --- only when multiple frames
rlm@449	522 #+caption: are analyzed together is the wiggling revealed. Defining
rlm@449	523 #+caption: wiggling this way also gives the worm an opportunity to learn
rlm@449	524 #+caption: and recognize ``frustrated wiggling'', where the worm tries to
rlm@449	525 #+caption: wiggle but can't. Frustrated wiggling is very visually different
rlm@449	526 #+caption: from actual wiggling, but this definition gives it to us for free.
rlm@449	527 #+name: wiggling
rlm@449	528 #+begin_listing clojure
rlm@449	529 #+begin_src clojure
rlm@449	530 (defn fft [nums]
rlm@449	531 (map
rlm@449	532 #(.getReal %)
rlm@449	533 (.transform
rlm@449	534 (FastFourierTransformer. DftNormalization/STANDARD)
rlm@449	535 (double-array nums) TransformType/FORWARD)))
rlm@449	536
rlm@449	537 (def indexed (partial map-indexed vector))
rlm@449	538
rlm@449	539 (defn max-indexed [s]
rlm@449	540 (first (sort-by (comp - second) (indexed s))))
rlm@449	541
rlm@449	542 (defn wiggling?
rlm@449	543 "Is the worm wiggling?"
rlm@449	544 [experiences]
rlm@449	545 (let [analysis-interval 0x40]
rlm@449	546 (when (> (count experiences) analysis-interval)
rlm@449	547 (let [a-flex 3
rlm@449	548 a-ex 2
rlm@449	549 muscle-activity
rlm@449	550 (map :muscle (vector:last-n experiences analysis-interval))
rlm@449	551 base-activity
rlm@449	552 (map #(- (% a-flex) (% a-ex)) muscle-activity)]
rlm@449	553 (= 2
rlm@449	554 (first
rlm@449	555 (max-indexed
rlm@449	556 (map #(Math/abs %)
rlm@449	557 (take 20 (fft base-activity))))))))))
rlm@449	558 #+end_src
rlm@449	559 #+end_listing
rlm@449	560
rlm@449	561 With these action predicates, I can now recognize the actions of
rlm@449	562 the worm while it is moving under my control and I have access to
rlm@449	563 all the worm's senses.
rlm@449	564
rlm@449	565 #+caption: Use the action predicates defined earlier to report on
rlm@449	566 #+caption: what the worm is doing while in simulation.
rlm@449	567 #+name: report-worm-activity
rlm@449	568 #+begin_listing clojure
rlm@449	569 #+begin_src clojure
rlm@449	570 (defn debug-experience
rlm@449	571 [experiences text]
rlm@449	572 (cond
rlm@449	573 (grand-circle? experiences) (.setText text "Grand Circle")
rlm@449	574 (curled? experiences) (.setText text "Curled")
rlm@449	575 (wiggling? experiences) (.setText text "Wiggling")
rlm@449	576 (resting? experiences) (.setText text "Resting")))
rlm@449	577 #+end_src
rlm@449	578 #+end_listing
rlm@449	579
rlm@449	580 #+caption: Using =debug-experience=, the body-centered predicates
rlm@449	581 #+caption: work together to classify the behaviour of the worm.
rlm@451	582 #+caption: the predicates are operating with access to the worm's
rlm@451	583 #+caption: full sensory data.
rlm@449	584 #+name: basic-worm-view
rlm@449	585 #+ATTR_LaTeX: :width 10cm
rlm@449	586 [[./images/worm-identify-init.png]]
rlm@449	587
rlm@449	588 These action predicates satisfy the recognition requirement of an
rlm@451	589 empathic recognition system. There is power in the simplicity of
rlm@451	590 the action predicates. They describe their actions without getting
rlm@451	591 confused in visual details of the worm. Each one is frame
rlm@451	592 independent, but more than that, they are each indepent of
rlm@449	593 irrelevant visual details of the worm and the environment. They
rlm@449	594 will work regardless of whether the worm is a different color or
rlm@451	595 hevaily textured, or if the environment has strange lighting.
rlm@449	596
rlm@449	597 The trick now is to make the action predicates work even when the
rlm@449	598 sensory data on which they depend is absent. If I can do that, then
rlm@449	599 I will have gained much,
rlm@435	600
rlm@436	601 ** \Phi-space describes the worm's experiences
rlm@449	602
rlm@449	603 As a first step towards building empathy, I need to gather all of
rlm@449	604 the worm's experiences during free play. I use a simple vector to
rlm@449	605 store all the experiences.
rlm@449	606
rlm@449	607 Each element of the experience vector exists in the vast space of
rlm@449	608 all possible worm-experiences. Most of this vast space is actually
rlm@449	609 unreachable due to physical constraints of the worm's body. For
rlm@449	610 example, the worm's segments are connected by hinge joints that put
rlm@451	611 a practical limit on the worm's range of motions without limiting
rlm@451	612 its degrees of freedom. Some groupings of senses are impossible;
rlm@451	613 the worm can not be bent into a circle so that its ends are
rlm@451	614 touching and at the same time not also experience the sensation of
rlm@451	615 touching itself.
rlm@449	616
rlm@451	617 As the worm moves around during free play and its experience vector
rlm@451	618 grows larger, the vector begins to define a subspace which is all
rlm@451	619 the sensations the worm can practicaly experience during normal
rlm@451	620 operation. I call this subspace \Phi-space, short for
rlm@451	621 physical-space. The experience vector defines a path through
rlm@451	622 \Phi-space. This path has interesting properties that all derive
rlm@451	623 from physical embodiment. The proprioceptive components are
rlm@451	624 completely smooth, because in order for the worm to move from one
rlm@451	625 position to another, it must pass through the intermediate
rlm@451	626 positions. The path invariably forms loops as actions are repeated.
rlm@451	627 Finally and most importantly, proprioception actually gives very
rlm@451	628 strong inference about the other senses. For example, when the worm
rlm@451	629 is flat, you can infer that it is touching the ground and that its
rlm@451	630 muscles are not active, because if the muscles were active, the
rlm@451	631 worm would be moving and would not be perfectly flat. In order to
rlm@451	632 stay flat, the worm has to be touching the ground, or it would
rlm@451	633 again be moving out of the flat position due to gravity. If the
rlm@451	634 worm is positioned in such a way that it interacts with itself,
rlm@451	635 then it is very likely to be feeling the same tactile feelings as
rlm@451	636 the last time it was in that position, because it has the same body
rlm@451	637 as then. If you observe multiple frames of proprioceptive data,
rlm@451	638 then you can become increasingly confident about the exact
rlm@451	639 activations of the worm's muscles, because it generally takes a
rlm@451	640 unique combination of muscle contractions to transform the worm's
rlm@451	641 body along a specific path through \Phi-space.
rlm@449	642
rlm@449	643 There is a simple way of taking \Phi-space and the total ordering
rlm@449	644 provided by an experience vector and reliably infering the rest of
rlm@449	645 the senses.
rlm@435	646
rlm@436	647 ** Empathy is the process of tracing though \Phi-space
rlm@449	648
rlm@450	649 Here is the core of a basic empathy algorithm, starting with an
rlm@451	650 experience vector:
rlm@451	651
rlm@451	652 First, group the experiences into tiered proprioceptive bins. I use
rlm@451	653 powers of 10 and 3 bins, and the smallest bin has an approximate
rlm@451	654 size of 0.001 radians in all proprioceptive dimensions.
rlm@450	655
rlm@450	656 Then, given a sequence of proprioceptive input, generate a set of
rlm@451	657 matching experience records for each input, using the tiered
rlm@451	658 proprioceptive bins.
rlm@449	659
rlm@450	660 Finally, to infer sensory data, select the longest consective chain
rlm@451	661 of experiences. Conecutive experience means that the experiences
rlm@451	662 appear next to each other in the experience vector.
rlm@449	663
rlm@450	664 This algorithm has three advantages:
rlm@450	665
rlm@450	666 1. It's simple
rlm@450	667
rlm@451	668 3. It's very fast -- retrieving possible interpretations takes
rlm@451	669 constant time. Tracing through chains of interpretations takes
rlm@451	670 time proportional to the average number of experiences in a
rlm@451	671 proprioceptive bin. Redundant experiences in \Phi-space can be
rlm@451	672 merged to save computation.
rlm@450	673
rlm@450	674 2. It protects from wrong interpretations of transient ambiguous
rlm@451	675 proprioceptive data. For example, if the worm is flat for just
rlm@450	676 an instant, this flattness will not be interpreted as implying
rlm@450	677 that the worm has its muscles relaxed, since the flattness is
rlm@450	678 part of a longer chain which includes a distinct pattern of
rlm@451	679 muscle activation. Markov chains or other memoryless statistical
rlm@451	680 models that operate on individual frames may very well make this
rlm@451	681 mistake.
rlm@450	682
rlm@450	683 #+caption: Program to convert an experience vector into a
rlm@450	684 #+caption: proprioceptively binned lookup function.
rlm@450	685 #+name: bin
rlm@450	686 #+begin_listing clojure
rlm@450	687 #+begin_src clojure
rlm@449	688 (defn bin [digits]
rlm@449	689 (fn [angles]
rlm@449	690 (->> angles
rlm@449	691 (flatten)
rlm@449	692 (map (juxt #(Math/sin %) #(Math/cos %)))
rlm@449	693 (flatten)
rlm@449	694 (mapv #(Math/round (* % (Math/pow 10 (dec digits))))))))
rlm@449	695
rlm@449	696 (defn gen-phi-scan
rlm@450	697 "Nearest-neighbors with binning. Only returns a result if
rlm@450	698 the propriceptive data is within 10% of a previously recorded
rlm@450	699 result in all dimensions."
rlm@450	700 [phi-space]
rlm@449	701 (let [bin-keys (map bin [3 2 1])
rlm@449	702 bin-maps
rlm@449	703 (map (fn [bin-key]
rlm@449	704 (group-by
rlm@449	705 (comp bin-key :proprioception phi-space)
rlm@449	706 (range (count phi-space)))) bin-keys)
rlm@449	707 lookups (map (fn [bin-key bin-map]
rlm@450	708 (fn [proprio] (bin-map (bin-key proprio))))
rlm@450	709 bin-keys bin-maps)]
rlm@449	710 (fn lookup [proprio-data]
rlm@449	711 (set (some #(% proprio-data) lookups)))))
rlm@450	712 #+end_src
rlm@450	713 #+end_listing
rlm@449	714
rlm@451	715 #+caption: =longest-thread= finds the longest path of consecutive
rlm@451	716 #+caption: experiences to explain proprioceptive worm data.
rlm@451	717 #+name: phi-space-history-scan
rlm@451	718 #+ATTR_LaTeX: :width 10cm
rlm@451	719 [[./images/aurellem-gray.png]]
rlm@451	720
rlm@451	721 =longest-thread= infers sensory data by stitching together pieces
rlm@451	722 from previous experience. It prefers longer chains of previous
rlm@451	723 experience to shorter ones. For example, during training the worm
rlm@451	724 might rest on the ground for one second before it performs its
rlm@451	725 excercises. If during recognition the worm rests on the ground for
rlm@451	726 five seconds, =longest-thread= will accomodate this five second
rlm@451	727 rest period by looping the one second rest chain five times.
rlm@451	728
rlm@451	729 =longest-thread= takes time proportinal to the average number of
rlm@451	730 entries in a proprioceptive bin, because for each element in the
rlm@451	731 starting bin it performes a series of set lookups in the preceeding
rlm@451	732 bins. If the total history is limited, then this is only a constant
rlm@451	733 multiple times the number of entries in the starting bin. This
rlm@451	734 analysis also applies even if the action requires multiple longest
rlm@451	735 chains -- it's still the average number of entries in a
rlm@451	736 proprioceptive bin times the desired chain length. Because
rlm@451	737 =longest-thread= is so efficient and simple, I can interpret
rlm@451	738 worm-actions in real time.
rlm@449	739
rlm@450	740 #+caption: Program to calculate empathy by tracing though \Phi-space
rlm@450	741 #+caption: and finding the longest (ie. most coherent) interpretation
rlm@450	742 #+caption: of the data.
rlm@450	743 #+name: longest-thread
rlm@450	744 #+begin_listing clojure
rlm@450	745 #+begin_src clojure
rlm@449	746 (defn longest-thread
rlm@449	747 "Find the longest thread from phi-index-sets. The index sets should
rlm@449	748 be ordered from most recent to least recent."
rlm@449	749 [phi-index-sets]
rlm@449	750 (loop [result '()
rlm@449	751 [thread-bases & remaining :as phi-index-sets] phi-index-sets]
rlm@449	752 (if (empty? phi-index-sets)
rlm@449	753 (vec result)
rlm@449	754 (let [threads
rlm@449	755 (for [thread-base thread-bases]
rlm@449	756 (loop [thread (list thread-base)
rlm@449	757 remaining remaining]
rlm@449	758 (let [next-index (dec (first thread))]
rlm@449	759 (cond (empty? remaining) thread
rlm@449	760 (contains? (first remaining) next-index)
rlm@449	761 (recur
rlm@449	762 (cons next-index thread) (rest remaining))
rlm@449	763 :else thread))))
rlm@449	764 longest-thread
rlm@449	765 (reduce (fn [thread-a thread-b]
rlm@449	766 (if (> (count thread-a) (count thread-b))
rlm@449	767 thread-a thread-b))
rlm@449	768 '(nil)
rlm@449	769 threads)]
rlm@449	770 (recur (concat longest-thread result)
rlm@449	771 (drop (count longest-thread) phi-index-sets))))))
rlm@450	772 #+end_src
rlm@450	773 #+end_listing
rlm@450	774
rlm@451	775 There is one final piece, which is to replace missing sensory data
rlm@451	776 with a best-guess estimate. While I could fill in missing data by
rlm@451	777 using a gradient over the closest known sensory data points,
rlm@451	778 averages can be misleading. It is certainly possible to create an
rlm@451	779 impossible sensory state by averaging two possible sensory states.
rlm@451	780 Therefore, I simply replicate the most recent sensory experience to
rlm@451	781 fill in the gaps.
rlm@449	782
rlm@449	783 #+caption: Fill in blanks in sensory experience by replicating the most
rlm@449	784 #+caption: recent experience.
rlm@449	785 #+name: infer-nils
rlm@449	786 #+begin_listing clojure
rlm@449	787 #+begin_src clojure
rlm@449	788 (defn infer-nils
rlm@449	789 "Replace nils with the next available non-nil element in the
rlm@449	790 sequence, or barring that, 0."
rlm@449	791 [s]
rlm@449	792 (loop [i (dec (count s))
rlm@449	793 v (transient s)]
rlm@449	794 (if (zero? i) (persistent! v)
rlm@449	795 (if-let [cur (v i)]
rlm@449	796 (if (get v (dec i) 0)
rlm@449	797 (recur (dec i) v)
rlm@449	798 (recur (dec i) (assoc! v (dec i) cur)))
rlm@449	799 (recur i (assoc! v i 0))))))
rlm@449	800 #+end_src
rlm@449	801 #+end_listing
rlm@435	802
rlm@441	803 ** Efficient action recognition with =EMPATH=
rlm@451	804
rlm@451	805 To use =EMPATH= with the worm, I first need to gather a set of
rlm@451	806 experiences from the worm that includes the actions I want to
rlm@451	807 recognize. The =generate-phi-space= program (listint
rlm@451	808 \ref{generate-phi-space} runs the worm through a series of
rlm@451	809 exercices and gatheres those experiences into a vector. The
rlm@451	810 =do-all-the-things= program is a routine expressed in a simple
rlm@451	811 muscle contraction script language for automated worm control.
rlm@425	812
rlm@451	813 #+caption: Program to gather the worm's experiences into a vector for
rlm@451	814 #+caption: further processing. The =motor-control-program= line uses
rlm@451	815 #+caption: a motor control script that causes the worm to execute a series
rlm@451	816 #+caption: of ``exercices'' that include all the action predicates.
rlm@451	817 #+name: generate-phi-space
rlm@451	818 #+attr_latex: [!H]
rlm@451	819 #+begin_listing clojure
rlm@451	820 #+begin_src clojure
rlm@451	821 (def do-all-the-things
rlm@451	822 (concat
rlm@451	823 curl-script
rlm@451	824 [[300 :d-ex 40]
rlm@451	825 [320 :d-ex 0]]
rlm@451	826 (shift-script 280 (take 16 wiggle-script))))
rlm@451	827
rlm@451	828 (defn generate-phi-space []
rlm@451	829 (let [experiences (atom [])]
rlm@451	830 (run-world
rlm@451	831 (apply-map
rlm@451	832 worm-world
rlm@451	833 (merge
rlm@451	834 (worm-world-defaults)
rlm@451	835 {:end-frame 700
rlm@451	836 :motor-control
rlm@451	837 (motor-control-program worm-muscle-labels do-all-the-things)
rlm@451	838 :experiences experiences})))
rlm@451	839 @experiences))
rlm@451	840 #+end_src
rlm@451	841 #+end_listing
rlm@451	842
rlm@451	843 #+caption: Use longest thread and a phi-space generated from a short
rlm@451	844 #+caption: exercise routine to interpret actions during free play.
rlm@451	845 #+name: empathy-debug
rlm@451	846 #+begin_listing clojure
rlm@451	847 #+begin_src clojure
rlm@451	848 (defn init []
rlm@451	849 (def phi-space (generate-phi-space))
rlm@451	850 (def phi-scan (gen-phi-scan phi-space)))
rlm@451	851
rlm@451	852 (defn empathy-demonstration []
rlm@451	853 (let [proprio (atom ())]
rlm@451	854 (fn
rlm@451	855 [experiences text]
rlm@451	856 (let [phi-indices (phi-scan (:proprioception (peek experiences)))]
rlm@451	857 (swap! proprio (partial cons phi-indices))
rlm@451	858 (let [exp-thread (longest-thread (take 300 @proprio))
rlm@451	859 empathy (mapv phi-space (infer-nils exp-thread))]
rlm@451	860 (println-repl (vector:last-n exp-thread 22))
rlm@451	861 (cond
rlm@451	862 (grand-circle? empathy) (.setText text "Grand Circle")
rlm@451	863 (curled? empathy) (.setText text "Curled")
rlm@451	864 (wiggling? empathy) (.setText text "Wiggling")
rlm@451	865 (resting? empathy) (.setText text "Resting")
rlm@451	866 :else (.setText text "Unknown")))))))
rlm@451	867
rlm@451	868 (defn empathy-experiment [record]
rlm@451	869 (.start (worm-world :experience-watch (debug-experience-phi)
rlm@451	870 :record record :worm worm*)))
rlm@451	871 #+end_src
rlm@451	872 #+end_listing
rlm@451	873
rlm@451	874 The result of running =empathy-experiment= is that the system is
rlm@451	875 generally able to interpret worm actions using the action-predicates
rlm@451	876 on simulated sensory data just as well as with actual data. Figure
rlm@451	877 \ref{empathy-debug-image} was generated using =empathy-experiment=:
rlm@451	878
rlm@451	879 #+caption: From only proprioceptive data, =EMPATH= was able to infer
rlm@451	880 #+caption: the complete sensory experience and classify four poses
rlm@451	881 #+caption: (The last panel shows a composite image of \emph{wriggling},
rlm@451	882 #+caption: a dynamic pose.)
rlm@451	883 #+name: empathy-debug-image
rlm@451	884 #+ATTR_LaTeX: :width 10cm :placement [H]
rlm@451	885 [[./images/empathy-1.png]]
rlm@451	886
rlm@451	887 One way to measure the performance of =EMPATH= is to compare the
rlm@451	888 sutiability of the imagined sense experience to trigger the same
rlm@451	889 action predicates as the real sensory experience.
rlm@451	890
rlm@451	891 #+caption: Determine how closely empathy approximates actual
rlm@451	892 #+caption: sensory data.
rlm@451	893 #+name: test-empathy-accuracy
rlm@451	894 #+begin_listing clojure
rlm@451	895 #+begin_src clojure
rlm@451	896 (def worm-action-label
rlm@451	897 (juxt grand-circle? curled? wiggling?))
rlm@451	898
rlm@451	899 (defn compare-empathy-with-baseline [matches]
rlm@451	900 (let [proprio (atom ())]
rlm@451	901 (fn
rlm@451	902 [experiences text]
rlm@451	903 (let [phi-indices (phi-scan (:proprioception (peek experiences)))]
rlm@451	904 (swap! proprio (partial cons phi-indices))
rlm@451	905 (let [exp-thread (longest-thread (take 300 @proprio))
rlm@451	906 empathy (mapv phi-space (infer-nils exp-thread))
rlm@451	907 experience-matches-empathy
rlm@451	908 (= (worm-action-label experiences)
rlm@451	909 (worm-action-label empathy))]
rlm@451	910 (println-repl experience-matches-empathy)
rlm@451	911 (swap! matches #(conj % experience-matches-empathy)))))))
rlm@451	912
rlm@451	913 (defn accuracy [v]
rlm@451	914 (float (/ (count (filter true? v)) (count v))))
rlm@451	915
rlm@451	916 (defn test-empathy-accuracy []
rlm@451	917 (let [res (atom [])]
rlm@451	918 (run-world
rlm@451	919 (worm-world :experience-watch
rlm@451	920 (compare-empathy-with-baseline res)
rlm@451	921 :worm worm*))
rlm@451	922 (accuracy @res)))
rlm@451	923 #+end_src
rlm@451	924 #+end_listing
rlm@451	925
rlm@451	926 Running =test-empathy-accuracy= using the very short exercise
rlm@451	927 program defined in listing \ref{generate-phi-space}, and then doing
rlm@451	928 a similar pattern of activity manually yeilds an accuracy of around
rlm@451	929 73%. This is based on very limited worm experience. By training the
rlm@451	930 worm for longer, the accuracy dramatically improves.
rlm@451	931
rlm@451	932 #+caption: Program to generate \Phi-space using manual training.
rlm@451	933 #+name: manual-phi-space
rlm@451	934 #+begin_listing clojure
rlm@451	935 #+begin_src clojure
rlm@451	936 (defn init-interactive []
rlm@451	937 (def phi-space
rlm@451	938 (let [experiences (atom [])]
rlm@451	939 (run-world
rlm@451	940 (apply-map
rlm@451	941 worm-world
rlm@451	942 (merge
rlm@451	943 (worm-world-defaults)
rlm@451	944 {:experiences experiences})))
rlm@451	945 @experiences))
rlm@451	946 (def phi-scan (gen-phi-scan phi-space)))
rlm@451	947 #+end_src
rlm@451	948 #+end_listing
rlm@451	949
rlm@451	950 After about 1 minute of manual training, I was able to achieve 95%
rlm@451	951 accuracy on manual testing of the worm using =init-interactive= and
rlm@451	952 =test-empathy-accuracy=. The ability of the system to infer sensory
rlm@451	953 states is truly impressive.
rlm@450	954
rlm@449	955 ** Digression: bootstrapping touch using free exploration
rlm@449	956
rlm@432	957 * Contributions
rlm@447	958
rlm@447	959
rlm@447	960
rlm@447	961
rlm@447	962 # An anatomical joke:
rlm@447	963 # - Training
rlm@447	964 # - Skeletal imitation
rlm@447	965 # - Sensory fleshing-out
rlm@447	966 # - Classification

Mercurial > cortex

annotate thesis/cortex.org @ 451:0a4362d1f138