Who Needs Emotions? The Brain Meets the Robot

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eware the passionate robot 379 Arbib, M. A., & Liaw, J.-S. (1995). Sensorimotor transformations in the worlds of frogs and robots. Artificial Intelligence, 72, 53–79. Arbib, M. A., & Rizzolatti, G., (1997). Neural expectations: A possible evolutionary path from manual skills to language. Communication and Cognition, 29, 393– 424. Betts, B. (1989). The T5 base modulator hypothesis: A dynamic model of T5 neuron function in toads. In J. P. Ewert & M. A. Arbib (Eds.) Visuomotor coordination: Amphibians, comparisons, models and robots (pp. 269–307). New York: Plenum. Bischoff-Grethe, A., Crowley, M. G., & Arbib, M. A. (2003). Movement inhibition and next sensory state predictions in the basal ganglia. In VI (A. M. Graybiel, M. R. Delong, & S. T. Kitai (Eds.), The basal ganglia (Vol. VI, pp. 267–277). New York: Kluwer Plenum. Blaney, P. H. (1986). Affect and memory: A review. Psychological Bulletin, 99, 229– 246. Brzoska, J., & Schneider, H. (1978). Modification of prey-catching behavior by learning in the common toad (Bufo b bufo L, Anura, Amphibia): Changes in response to visual objects and effects of auditory stimuli. Behavioural Processes, 3, 125– 136. Christianson, S.-Å. (Ed.) (1992). The handbook of emotion and memory: Research and theory. Hillsdale, NJ: Erlbaum. Cobas, A., & Arbib, M. (1992). Prey-catching and predator-avoidance in frog and toad: Defining the schemas. Journal of Theoretical Biology, 157, 271–304. Coetzee, J. M. (2003). The Lives of Animals: ONE: The Philosophers and the Animals, being Lesson 3 of the novel Elizabeth Costello. New York: Viking. Damasio, A. R. (1994). Descartes’ error: Emotion, reason, and the human brain. New York: Grosset/Putnam. Dean, P., Redgrave, P. (1989). Approach and avoidance system in the rat. In M. A. Arbib & J-P. Ewert (Eds.), Visual structures and integrated functions. Research Notes in Neural Computing. New York: Springer-Verlag. Dean, P., Redgrave, P., & Westby, G. W. M. (1989). Event or emergency? Two response systems in the mammalian superior colliculus. Trends in Neuroscience, 12, 138–147. de Waal, F. (2001). The ape and the sushi master: Cultural reflections by a primatologist. New York: Basic Books. Dominey, P. F., & Arbib, M. A. (1992). A cortico-subcortical model for generation of spatially accurate sequential saccades. Cerebral Cortex, 2, 153–175. Ewert, J.-P. (1984). Tectal mechanisms that underlie prey-catching and avoidance behaviors in toads. In H. Vanegas (Ed.), Comparative neurology of the optic tectum (pp. 247–416). New York: Plenum. Ewert, J.-P. (1987). Neuroethology of releasing mechanisms: Prey-catching in toads. Behavioral and Brain Sciences, 10, 337–405. Fagg, A. H., & Arbib, M. A. (1998). Modeling parietal–premotor interactions in primate control of grasping. Neural Networks, 11, 1277–1303. Fellous, J. M. (1999). Neuromodulatory basis of emotion. Neuroscientist, 5, 283–294.
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TLFeBOOK Who Needs Emotions? The Br
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The Nature of Emotion: Fundamental
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3 Oxford University Press, Inc., pu
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vi preface want their computer prog
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viii preface is required because th
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x preface prefer to read Part III b
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xii contents PART III: ROBOTS 7 Aff
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xiv contributors Jean-Marc Fellous
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4 perspectives RUSSELL: I confess t
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6 perspectives EDISON: Tinkering! Y
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10 perspectives HOW COULD WE TELL I
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12 perspectives This, of course, ra
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14 perspectives of a stimulus (e.g.
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16 perspectives an emotion is neith
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18 perspectives cognitive processes
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20 perspectives that they visually
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22 perspectives A self-model that c
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24 perspectives Brothers, L. (1997)
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30 brains specificity and flexibili
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32 brains It is useful to begin wit
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34 brains the readout of that syste
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36 brains A. 5 NH 4Cl Bacteria in c
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38 brains Although instinctual beha
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40 brains Motivated behavior requir
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42 brains emerged through decades o
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44 brains and gonadal and adrenal s
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46 brains voluntary control of acti
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48 brains A. Total cerebral input t
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50 brains sensory neurons, interneu
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52 brains functions. Niall (1982) n
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54 brains motivation arousal necess
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56 brains serotonergic system is pr
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58 brains as tree jumping (Doudet e
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60 brains then have a system that a
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62 brains heroin and other opiates,
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64 brains benefits that also presen
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66 brains and brain neurotransmitte
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68 brains Cardinaud, B., Gilbert, J
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70 brains Hess, W. R. (1957). The f
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72 brains MacLean, P. D. (1990). Th
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74 brains Pfaus, J. G., Damsma, G.,
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76 brains trained monkeys: Agonist
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80 brains We conclude by discussing
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82 brains to prove, theoretical dis
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84 brains is a mammalian specializa
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86 brains processing circuits to se
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88 brains amygdala) and the control
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90 brains comparison of the amygdal
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92 brains Is the Amygdala Necessary
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94 brains the amygdala to determine
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96 brains The medial prefrontal cor
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98 brains Many questions remain to
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100 brains by the amygdala might be
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102 brains United States, pair up w
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104 brains networks that participat
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106 brains Note Portions of this ch
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108 brains Davidson, R. J., & Irwin
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110 brains mediate emotional respon
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112 brains Salinas, J. A. (1995). I
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114 brains and thalamo-cortico-amyg
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118 brains and flexible in the orbi
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120 brains Pleasure Rage Anger Frus
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122 brains of the eliciting stimulu
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124 brains or a right turn to obtai
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126 brains cortex and basal ganglia
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128 brains tex of recent (episodic)
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130 brains the right value in the c
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132 brains by the process of condit
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134 brains memories to be held in p
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136 brains However, it may be expec
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138 brains Figure 5.4. Some of the
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140 brains acting through the ventr
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142 brains (cutting white matter) w
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144 brains References Alexander, R.
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146 brains Rolls, E. T. (1999a). Th
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148 brains directed to us or when t
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150 brains Specific methods, partly
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152 brains Movements performed by l
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154 brains processing of invariant
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156 brains more about them, their r
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158 brains see Zajonc, 1985), the i
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160 brains The question now arises
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162 brains situations where they ha
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164 brains Estimation of social con
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166 brains Davies, M., & Stone, T.
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168 brains Lhermitte, F. (1983). Ut
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174 robots perform unanticipated ta
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176 Table 7.1. Principal Organism F
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178 robots and cognitive domains. A
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180 robots that they are better tho
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182 robots irregularities or discon
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184 robots 3. A (positive) feeling
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186 robots We consider the well-est
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188 robots disturbed by the approac
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190 robots processing. We view para
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192 robots independent, a value on
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194 robots Implications of the Proc
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196 robots current affective state
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198 robots primitive fear at the ro
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200 robots Gray, J. A. (1990). Brai
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202 robots cesses underlying approa
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204 robots case of CogAff, conjectu
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206 robots some cases and in other
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208 robots DIRECT AND MEDIATED CONT
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210 robots Toward a Useful Ontology
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212 robots different varieties of m
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214 robots Primitive sensors provid
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216 robots Being in a state P of a
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218 robots terms of the ability to
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220 robots Varieties of Affective S
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222 robots Central Perception Actio
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224 robots control, where all the l
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226 robots layer (e.g., observing p
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228 robots are sometimes unclear, i
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230 robots for such a fast-acting s
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232 robots from mental processes ot
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234 robots The majority view in thi
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236 robots Will it be a long-term f
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238 robots or implicitly adopted de
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240 robots some undesirable emotion
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242 robots References Albus, J. S.,
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244 robots Sloman, A. (2001b). Evol
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246 robots state variables such as
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248 robots In order to make robots
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250 robots motivational state also
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252 robots Prey acquisition: This b
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254 robots Figure 9.3. Top photos:
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256 robots especially when young. E
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258 robots Object of Attachment Saf
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260 robots Mean distance to attachm
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262 robots 2003), but the intent is
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264 robots Affective State Emotion
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266 robots Motivational/emotional m
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268 robots Brooks, R. (1986). A rob
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272 robots responsible for perceivi
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274 robots species considered to be
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276 robots This endeavor does not i
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278 robots For example, the person
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280 robots mental states (i.e., int
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282 robots Expression of Affective
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284 robots Negative valence High ar
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286 robots and emotion-related proc
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288 robots For instance, the visual
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290 robots Undesired stimulus Rejec
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292 robots intensity: seek or acqui
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294 robots Table 10.2. Summary of t
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296 robots it up (Breazeal, 2002b).
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298 robots pitch, f o (kHz) pitch,
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300 robots Table 10.3. Overall Clas
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302 robots Each emotion gateway pro
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304 robots Biasing Attention Kismet
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306 robots be to vocalize to the pe
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308 robots References Ackerman, B.,
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310 robots Center for the Study of
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312 robots When team members align
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314 robots effects that the agent h
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316 robots double arrow), which imp
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318 robots that of “robot as avat
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320 robots terms of specific apprai
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322 robots their own self-survival
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324 robots explicit, intended commu
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326 robots Although, the emotion
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Page 351 and 352: 334 conclusions handout and pleased
Page 353 and 354: 336 conclusions emotion. How can we
Page 355 and 356: 338 conclusions Presumably, the fac
Page 357 and 358: 340 conclusions Absence of N and N
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Page 363 and 364: 346 conclusions approach to the soc
Page 365 and 366: 348 conclusions at the much higher
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Page 371 and 372: 354 conclusions pathway of much mor
Page 373 and 374: 356 conclusions The Motivated Toad
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Page 377 and 378: 360 conclusions directly and by pro
Page 379 and 380: 362 conclusions striatum pallidum d
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Page 391 and 392: 374 conclusions much of my behavior
Page 393 and 394: 376 conclusions Consider a robot th
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Page 399 and 400: 382 conclusions Localization of gra
Page 403 and 404: 386 index amygdala back projection,
Page 405 and 406: 388 index cognition (continued) evo
Page 407 and 408: 390 index emotion research (continu
Page 409 and 410: 392 index fear conditioning (contin
Page 411 and 412: 394 index limbic system theory, 80-
Page 413 and 414: 396 index prefrontal cortex and the
Page 415 and 416: 398 index schema theory and Jackson
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