Download Machine Intelligence: The Death of Artificial Intelligence

THINKINGSOLUTIONS1998
MACHINEINTELLIGENCE:
T H E D E AT H O F A RT I F I C I A L
INTELLIGENCE
J O H N B A L L
FIRSTWRITTEN
SEPTEMBER26,1998
Copyright©1998and2016byJohnBall
Allrightsreserved.Nopartofthispublicationmaybereproduced,distributed,or
transmittedinanyformorbyanymeans,includingphotocopying,recording,orother
electronicormechanicalmethods,withoutthepriorwrittenpermissionofthepublisher,
exceptinthecaseofbriefquotationsembodiedincriticalreviewsandcertainother
noncommercialusespermittedbycopyrightlaw.
FirstEditionSeptember26,1998
ThinkingSolutions,LindfieldNSW
SecondEditionApril15,2016
HiredPenPublishing,Seattle,WA
TABLEOFCONTENTS
PREFACE
Whycare?
IsAIintelligenttoday?
TheproblemwithlanguageinAI
Today
Thefutureisbright
OVERVIEW
DESIGNQUESTIONS
ASSUMPTIONS
THEMODEL—AQUICKSNAPSHOT
INTRODUCTION
GOALS
THEDEATHOFAI
WHODOWEMODEL?
ROBOTPRODUCTION
WHYHASPROGRESSBEENSLOW?
DEATHOFPROCESSING
DEATHOFTHEPROCESSINGMODEL
DOESITADDUP?
THEMACHINE
SENSES
MACHINEINTELLIGENCEMEMORY(MIM)
OURBRAIN’SCONSTRUCTION(MICONSTRUCTION)
MIOPERATIONS
Sleep
COMPARISONTODAVIDHUME’SMODEL
PATTERNMATCHING,LEARNINGANDUNLEARNING
MORECOMPLEXSENSES
LANGUAGE
LanguageExample
LanguageUnderstanding
Hutchens’LoebnerPriZeProgram
VISIONSYSTEM
Recognitionofspelling
Recognitionofwords
Recognitionoffaces
HUMANEXAMPLES:PHYSIOLOGY,PSYCHOLOGY&PHILOSOPHY
PHYSIOLOGY
FREUD
ratman
CARLJUNG
Jung’sFreeAssociation
PLATO
PAVLOV’SDOG
B.F.SKINNER
DAVIDHUME
SCIENCE85—THECONFESSION
WALDROPINTRODUCTION
ROGERSHANK’SDEFINITION
THOMASOPOGGIO:MATHEMATICIANOFVISION
BRUCEBUCHANAN:MAKINGKNOWLEDGEUSEFUL
GEOFFREYHINTON:PARALLELINTELLIGENCE
TERRYWINOGRAD:ENGLISHASACOMPUTERLANGUAGE
HUBERTDREYFUS:THEBLACKNIGHTOFAI
THEROOTSOFMORALITY
IMPLICATIONSOFMIMTHEORY
HERIDARYVALUE
CONCLUSION
APPENDIXA.ADDITIONANDMULTIPLICATIONWITHOUTPROCESSING
APPENDIXB.ASSUMPTIONS
FURTHERREADING
P REFACE
UPDATED2016
We sit at the threshold of the next generation of computing, in which machines
understandusanddowhatwewant.TheyrequirenaturallanguageunderstandingorNLU.
My lab now produces programs that solve open scientific problems based on patternmatchingasdescribedinthisbook:forunderstanding,translationandconversation.Ifyou
learnonethingfromthisbook,Iwantittobethattheapproachismoreimportantthanthe
effort. In the same way that predictions in astronomy weren’t revolutionized by more
effort on an earth-centric model, redefining the model to fit the reality of a sun-centric
modelwasneeded.
This book was first written in 1998 and formed the basis for what subsequently
becameknownasPatomtheory,abrain-basedtheoryinwhichbrainsaremodelledwith
pattern-matching elements that simply store, match and use hierarchical, bidirectional
linksetpatterns.IchuckledwhenIreadsomeofmyexplanationsfrombackthenbecause
themodelhasbeenclarifiedthroughthescientificmethodwithextensivetrialanderror.
Science progresses as people work through today’s limitations. As in 1998, the biggest
technologicalproblemstodayseemtobeinthecognitivesciences,notsomuchinphysics
or biology. The branches of cognitive science relating to computational models have
proliferated,butremainineffectiveatsolvingcoreproblems,likelanguageunderstanding
(NLUcontrastswithartificiallanguages,likeJavaorC#).
This book makes you think about the actual problem of machine intelligence by
lookingatthefactsofouramazinghumancapabilities:allprovidedbyourbrain.
Patom Theory aligns more closely with the brain than the model described on these
pages,butthefoundationalconceptforthetheoryiseasiertofollowhere.Theproblemit
solvesisthesame,andthemodelhasevolvedtomoreaccuracy.Theprocessingmodelat
thecoreofacomputerisstillaninhibitortoemulatingbrainfunction.Thequestionsof
parallel processing— a popular computing paradigm—are now dealt with by learned
connections within the network, rather than broadcasting from a central controller.
Conceptually the model is the same, but the implementation is now working with a
simpler design. Similarly, the question of how much fuzzy logic and statistics to use is
replacedwiththealternativeapproachofperfectaccuracywithinalandscapeofconsistent
ambiguity.
WHYCARE?
YoumaythinkIregardtoday’sstate-of-the-artincomputersandArtificialIntelligence
negatively, but nothing could be further from the truth. Computers today remain
remarkablemachinesthathavetransformedourlivesforthebetter.Mostthingsthatcan
bedescribedasaseriesofstepshavebeenprogrammedonacomputer,aspredictedbythe
founding fathers of AI in 1956. But the things that haven’t been achieved that were
expected, like vision and conversational language understanding systems, are not here
todaydespitedecadesoftryingbyverysmartpeople.
Programmers failed in the 1970s to outperform statistical approaches. Statistical
systems won that battle, but remain lacking in human accuracy and worse, their current
limitations seem to conjure up fear amongst physicists and entrepreneurs alike, who
predictillogicalresults.Imean,Hollywoodlovestopredicttheendofhumanitythrough
runawayAI.FirsttheAIbecomesmoreintelligentthanus.Aminuteorsolater,having
surpassed the Kurzweil singularity, it creates an automated factory to mass produce
machinesthatexcelineveryaspectofroboticsthathumanshavefailedat,todate.And
then,Armageddon!
ISAIINTELLIGENTTODAY?
Toputthesefearsinperspective,today’sAIisnotintelligent.Onascaleof0to100,
where0waswherecomputerswereatwhenAlanTuringwroteabouttheTuringtestin
1950, and 100 which is human-level intelligence, we are around a 10. Machines don’t
understand,andthereforecannotbeintelligent,regardlessofthespeedofprocessorsorthe
sizeofmemory.Basedonthespeedatwhichwecouldmigratetolanguageunderstanding
systems,Ipredictmachinescansurpasshumansaround2040assumingwepursueNLUas
wedidwithpersonalcomputersandthenphonehandsets.
Now what about these murderous robots in our future? Firstly, why would an
intelligent machine be able to create robots more effectively than humans today? If
creativity comes from the application of problems to new domains, and AI uses a
paradigm unlike human brains, why do we think a super-fast machine will get the right
answers? If it’s trial and error, and the machine is faster, it still needs to outperform
thousands of humans and millions of dead ends. I can’t buy the idea that machines will
generalize any time soon, but when they do, they will do it like we do. Secondly, if an
intelligentmachinereliesonus,whywoulditnotwanttoworkwithus?Ifitistoostupid
tounderstanditreliesonustosurvive,whydowethinkitwillbesmartenoughtobeatus
in a competition against us? Wouldn’t we turn it off? How could it stop us? Create an
armyofrobots?Nuclearwar?
Forthosesciencefictionenthusiastswhoknowthestoryof2001:ASpaceOdyssey,
remember that even the HAL9000, a machine that would probably exceed human-level
intelligence,wasunabletostopDavidBowmanfromturningitoff.Imean,ifIwereHal,I
wouldhavelockedtheexternalhatch,orblockedtheairflowsomehow.Whatadummy!
THEPROBLEMWITHLANGUAGEINAI
I have used the term ‘Machine Intelligence’ to describe brain-based machines that
emulatehumanintelligence.While‘artificialintelligence’orAIisawell-knownterm,it
alsobringsitsassociationsofcomputation,programmingand,ifImaysayso,failure.AI
hasbeenhypedtodeath,sorry,butithasmany,many,many,many,manytimes.Solet’s
welcomeMI.
David Hume, an amazing person from our history, developed a model of brain
association. He explained sensory experience as impressions, the direct input of
experience,andideas,thefaintermemoryofstoredexperience.Ideasarebrainmemories,
brokendownimpressionscomprisedofthecomponentparts.Thebrainisfreetocombine
ideaswithoutconstraint.Humearguedthatthebestwaytodealwithourcreativeabilityis
to condemn all ideas to the flames that have not become ideas from direct sensory
experiencedirectly.
We need MI to embrace Hume’s teachings. If intelligence comes from the
combinations of experience, we need machines to break the world into its constituent
meanings,inwhichmeaningcomesfromexperience.Ahorsewithwingsisplausible,but
experiencerulesitout.Physicsandanatomyalsoruleitout,butthatisamorecomplex
story.
Whiletherearesomeideasthathavefallenbythewaysidetoremovethehomunculi
from our brain, the text is still, in my humble opinion, a good introduction to a way to
approachbrain-basedresearchinanobjectivemanner.
TODAY
A lot has happened since this book was written in an attempt to make systems act
intelligently.WenowhavetheiPhone,Siri,GoogleandMicrosoftCortana.TheInternetis
pervasive.WehaveIBMWatson,amachinethatdoesnotunderstandthewordsitmines,
butisrelieduponbyexpertstofindinformationwrittenindocuments.
Industry uses words to obfuscate for marketing reasons. IBM Watson, for example,
call their machine a “cognitive system”, but a search on Google identifies cognition as:
“thementalactionorprocessofacquiringknowledgeandunderstandingthroughthought,
experience,andthesenses”.Itisunlikelythatalogicalargumentcanbemadetojustify
the components of Watson as cognitive because it doesn’t understand words. It doesn’t
havesenses.SowhycallaBigDataapplicationacognitivesystem?
Thesectiononassumptionsisnearthebeginningofthisbook.Meaningcomesfrom
words,andassociationsareverypowerful.Forthatreason,wordsthatareambiguousare
removed from the discussion on brains to add clarity. As another example, the Deep
NeuralNetworksofProfessorHintonhavebeenrenamed“DeepLearning”toalignwith
today’sobsessionofstatisticalgathering.Machinelearningissimilarlypopular.Usinga
known word like “learning” makes people think of its meaning. Learning suggests the
steps a person’s brain uses to break down meaning. Somehow, it accurately generalizes
fromlearning.ThetroubleisthatDeepLearningsimplychangesthestatisticalvaluesin
an artificial neural network with setup from people. When applied to the problem of
convertingspeechtotext,forexample,thereisnoknowledgeofthemeaningofthewords
foundatallbecausethedataisnotavailable.
Big data, neural networks, hidden markov models (HMM) and other statistical
solutionsareallsimilarmodels.Whentheresultsarewrong,well,whynottrysomething
elsetosolvethescience?ToparaphrasethelatefounderofIBM,ThomasJ.Watson,Sr:
“Itisbettertoaimatperfectionandmissit,thantoaimatimperfectionandhitit.”
THEFUTUREISBRIGHT
Today’sAItechnologieshavebeenbuiltoncomputers.Digitalcomputers,machines
builttoemulatehumancomputers,areawesomemachinesatwhattheyaredesignedtodo.
They run systems for industry. They run the internet. They are at the heart of science,
facilitating simulations of complex systems. But they are fundamentally flawed for AI
becausetheirstrengthsopposethebiologicalsystem’sdesign.
They start with unambiguous information, and carry out sequential steps to process
results.AnythingthatcanbecomputedcanbesolvedwithaUniversalTuringMachine,
theprinciplebehindeverycomputertoday.Buthumancomputersweren’tdesignedtodo
whattheirbrainsdo—see,hear,speakandmove.Theyweredesignedtocalculate.Ilike
tosaythat:
Today’sdigitalcomputerscompressandduplicateinformation.
Brainscentralizeandexpandinformation.
Computerscreateaknowledgeacquisitionbottleneck,byforcingaprogrammer
todefinethegeneralbeforestoringthespecifics.
Brainsstorethespecific,tofindthegeneralthroughexperience.
Wecanemulatethebrain’smodeltoday.Therearemanyfeaturesoflanguagethathave
been discovered and by looking at the science of language as it applies to meaning and
conversation, such as the Role and Reference Grammar, the future promises many new
applicationsthatwillaffectourdailylives.Wejustneedtostart.
Andwiththestart,wecanbenefitfromthescience.Sincemoderncomputersdeveloped
from the 1940s, scientific debates over strategies have raged. Today, many good ideas
since the 1950s are shelved, waiting to be re-evaluated in light of today’s amazing
improvementsinsoftwareengineering.
SomesaythattheHolyGrailofAIisNLU,sowecantalktoourdevicesnaturally.We
nowknowthatnotonlydoweneedtounderstandwhatisbeingsaid,butwhatisbeing
saidrelatestothemeaningandcommunicationsabouttherealworld.Thisisthestartof
theexploitationofbrain-basedtechnology.Wewillallenjoytheride.
JohnBall
PaloAlto,CA
April2016
O VERVIEW
September26,1998
Machine Intelligence requires the work of cognitive Scientists to deliver a design.
Cognitivesciencecombinesanumberofdisciplineswiththeaimofproducingintelligent
machines. The experience of computer scientists, linguists, neuroscientists, philosophers
andpsychologistsprovidesabasisforunderstandingthehumanbrain.Usingadesign-byimitationmethod,weshouldbeabletocreateanintelligentmachine.
The reality is that these people have been unsuccessful in making progress in what
appears to be the challenge of the century— in a century where many of the scientific
challenges(atomictheory,astronomy,andtraveltothemoon)havebeenconquered.
Creatingmachinesthatinteractwithusnaturallytrulyisthechallengeofthecentury.
Spoken and written language is better for communications than windows, mice and
keyboards. For machines to move in our world probably means using arms and legs
becausetheyarebetterthanwheelstodealwiththingslikestairsanddoors.Andsystems
thatcanusessensoryexperience–vision,hearing,balance,touch,tasteandsoonwillalso
changehowwedealwithmachines.
Machines to-date have been designed with people in mind as the users. A computer
revolutiongaveusamousetoaugmentakeyboard,butthatisonlyusefultothehuman
driving it. Speech should be faster because we are so fast at talking. We have video
cameras and televisions, but they are designed to record and show humans moving
pictures, synchronized with sound. Unlike brains that recognize images in real time and
the objects that sent the image, the recorded data of the moving image is optimised to
reproduceitforhumanconsumptiononanotherdevice,nottounderstandtheimages.The
recordingisacompressedversionofvision.
Themostextremecaseofahuman-centricdeviceis,infact,thedigitalcomputer,the
machine that replaces human computers. Human computers knew what the numbers
representedontheirnotepads,digitalcomputersdon’t.Theyknewwhatthestepswereto
manipulate the numbers. And they require a human to write the program. Today, all
computeroperationsarecontrolledbyaprogramwrittenbyaperson,orconvertedfroma
person’shigher-levelprogram.
Thesolutiontothechallengewillbeseenwithmachinesthatarenotprogrammed,but
learnandinteractbasedonexperience.Andtheywon’tneedustolearnhowtointeract
withthem,becausetheyinteractlikeotherpeople.
This paper asks a central question: if the human brain and nervous system is a
machinethatprovidesalltheobjectiveandsubjectiveobservationsofhumanability,what
designandcomponentsarerequiredtobuildamachinethatemulatesitsperformance?
Foryears,theworkinartificialintelligenceputforwardbycomputerscientistssince
the early Von Neumann and Turing computers are typically based on computational
models. The computational model has served the commercial and scientific market for
manyyearswithgreatsuccessandtherearemanyproblemsthatarewellsolvedbythese
electroniccomputers.Wherewouldwebetodaywithoutcomputersforbanking,finance
and air travel? Unfortunately, this computational model is too different to the human
process of “thinking”. If it were not so different, why would so many great thinkers be
unabletoproduceanartificialintelligence?
A way forward is to produce a model that explains the available observations. By
meeting the wide-ranging observations and by finding simple models that can emulate
these, we can explain the workings of the human brain—and therefore create the seeds
requiredtogrowanintelligentmachine.
Abetterwaytoapproachthechallengeofcreatinganintelligentmachineistodiscard
thecomputationalmodelinfavourofamemory-basedmodel.Thismodelprovidesavast
storage capacity and an even vaster number of links between stored items. Through the
processofassociation,thememorylinksarecreated.
Amazingly,thisnon-intelligentprocessprovidesthebasisforintelligentaction.This
modelresultsinthedetectionofarchetypalobjectsthroughtheprocessoflinkingobjects
togetherbyassociation.Italsoproduceslanguagethroughamulti-levelpatternmatching
facility. It even explains the observations of psychologists, linguists and philosophers
throughouttheages.
Itisevenmoreexcitingtofindthatthebraincanbemodelledbyasinglehardware
designthatisbothsimpleandversatileinapplication.Andthemodelisbasedonjusttwo
key elements: memory, and linkage to other memory. Processing, the basis of electronic
computingsincethe1950s,iseliminatedasthedominantelement.
D ESIGN Q UESTIONS
Inordertodesignanything,thequestionmustbeasked:“Whatdoesthishavetodo?”
A study of available material indicates that in order to imitate the human brain, our
best and only example of intelligence, there are a number of features we must emulate.
Thesefeaturesinclude:
The ability to recognise objects (visual, auditory, kinaesthetic, gustatory,
olfactory)inamatterofsubseconds,despitethefactthatthepartscomprisingthe
brainaremillionsoftimesslowerthanthefastestcomputers.
Theabilitytothrowaball,despitethefactthatthespeedofthethrowexceeds
thebrain’sabilitytocontroltheevent.
Theabilitytorun,includingthehugenumberofactivitiesthatmustbemanaged
simultaneouslytoensurebalance,controlandpace.
The ability to speak intelligible sentences, using correct grammar, context,
emotional intensity, and including a huge array of background and other
associated knowledge. This ability also despite the fact that the brain is far
slowerthanacomputer,andyetacomputerissopooratdoingthistask.
Thegenerationofaself-maintainingdatabaseabouttheworld.Thebrainlearns
from experience and the environment with no need for anyone to assist in the
managementofthedata(withtheexceptionofpsychologicalproblems).
Theabilitytolearn,withouttheneedfortraining.Examplesoflearnedabilities
includetheacquisitionoflanguage.
Andtheneedforanymodelofthebraintoalsoexplainthemanyobservations
thathavefedintothesystemsofphilosophicalandpsychologicalthoughtforthe
past3000yearsandmore.
Thebrainisanamazingorgan—thereismuchwehaveobservedaboutit,andsolittle
wehaveimitated,althoughwithsomuchemotionalbaggageandsomuchtheologicaland
philosophicalmisinformation,itisnowonder!
ThemodelproposedbyWilliamofOckhamisasoundonetouseinthemodellingof
thehumanbrain.Thatis:“entitiesarenottobemultipliedbeyondnecessity”.Takingthis
basicpremise,themodelprogresseswithacoupleofadditionalobservations:
1. The brain does not calculate in a way similar to a computer (there is no
evidence)
2. Thebrainrecognisesobjects
3. Thebrainassociatesobjectswithotherobjects
4. Thebraincanrecallobjectsandtheirassociationsattimes,whenrequired.
A SSUMPTIONS
Humanity is slow to modify its way given a sufficient number of incorrect
assumptions to a better way. Change requiring the eliminations of existing patterns and
associations are not often handled well by people—a likely result of our brain’s inner
workings. History often finds changes occur best after the death of a strong leader—at
leastintheirspecificareaofinfluence.
The new theory challenges several long-held assumptions about how we learn and,
indeed, what our brain is doing. Brains learn. Whether it is vision, speech, language or
how to perform calisthenics, brains learn these skills. Computers are programmed by
humans.
Ourworldisambiguous.Computersaredesignedtoremoveambiguity.
We associate to learn. We manipulate others by using words that associate others to
knownideas.Today’sbrainscienceishinderedbyusingsuchterms,especiallycomputer
termslikeprocessing,becauselikeitornot,thebrainthenaccessestheassociationsand
inhibitscontraryideas.
The theory described in this book challenges many of the assumptions we hold
concerningthehumanbrain.Thewordsthatimpactourabilitytotalkaboutbraintheory
includethefollowing(refertoappendixBformoredetail):
Thebrainandnervoussystemisamachinewecancopy.
Thereisnomind.
Thereisnoconsciousness.
Thereisnosubconsciousorunconsciousmind.
Dreamsdonothavemeaning.
Psychoanalysisisamethodofunderstandinglearning.
Humanthoughtisanoutcomeproducedbythebrain—itisnotasingleprocess.
Thoughtisnotacomputationalprocess.
Computermemorydoesnotworklikehumanmemory.
In the tradition of science defined by Ockham’s Razor, these assumptions focus the
investigation to construct an intelligent machine and avoid the many limitations put
forward by philosophers when explaining why they believe that intelligent machines
cannot be produced. They believe that the reason artificial intelligence will fail is its
inability to explain the observation of consciousness. The assumptions listed above are
merely some of the preconceived limitations retarding the progress towards creating
intelligentmachines,yet,theyarecentraltothecorrectpathahead.
T HE M ODEL —AQ UICK S NAPSHOT
In the theory set forth in this paper, the brain is assumed to be a pattern matching
system, with modules in the brain corresponding to areas representing specific memory
typesandwithlinkagesbetweenmemoryelementsproducingthemarvellousexperiences
oflife.Eachmemoryelementisanareathatcanrecognisepreviouslyexperiencedsensory
information and feed that information back through the system to produce a vague
imitationoftheoriginalmemory,ifrequired.
Thismodelofthebrainleadstoamachineintelligencemodelthatstatesintelligence
is a system of Machine Intelligence Memory (MIM) components linked together to
produce a large-scale sensory-linked system providing immediate recall of linked
informationonastatistical(mostorleastlikely)basis.
I NTRODUCTION
Therehavebeenmanywhoclaimthatintelligentmachinesarejustaroundthecorner.
Therehavebeenlargeprojectsaimedatcreatingspeakingmachines,inferencemachines
and machines with networks of elements that look like neurons to some degree. In the
1980s, Japan set about the production of the so-called 5th generation project to
revolutionisethecapabilityofcomputers.
Theseclaimshaveallbeenshowntobeoutrageouslyinaccurate.Regrettably,thelarge
amountsofmoneyandeffortappeartohavebeenputintoprojectsthatdidn’thaveaclear
result. They were pure research projects into areas where at best the description of the
projectscanbecalledguesswork.
This book considers a different approach. It outlines what is known about our best
intelligent model—human beings. By using a human being and creating a “thought
experiment” (Einstein had great success with this approach), we can venture into the
worldofintelligentmachinesandseewhatmakesthemtick.
So, can we use what we know about brains, and the human brain in particular, to
createanintelligentmachinetoday?Inourquestforprogress,humanshavealwaysbeen
successful in building machines once we have a good vision of our goal. Provided the
machineisdescribedinsufficientdetail,itismerelyaquestionofeffort(readmoneyin
today’seconomicclimate)toproducetorequiredoutcome.Themodelputforwardinthe
followingpagesshowsmanyofthecomponentsrequiredtocreatemachineintelligence.
Shouldthismodelbefollowed,anintelligentmachinewillbetheresult.
Rarelydoesanunclearstrategyproduceaclearoutcome!
Thequestionoffundinginacapitalistsocietyisadrivingforce.Thefirstcompanyto
produceanintelligentmachinewillchangethefaceofcomputingforever—relegatingthe
desktop computer to the failed automation tool of the 1950s to the 1999s. This would
representatrulydarkperiodinhumanhistory.
With the construction of intelligent machines, the Internet will become a haven for
machinesthattalk,sellandprovideotherservices.
Theendofthedesktopcomputerisnear.Thenewmachinesofthefuturewillspeakin
nativehumanlanguagesandprovidethetypeofcompanionshippreviouslyonlypossible
throughtheexploitationofslavesandservants.
ANewWorldisuponus!Readontoseewhy…
G OALS
Asimplemodelexplainseverything.Whereisthesimplemodelforbrainfunction?
The Greeks in the centuries before Christ dreamed of demons and Gods who were
able to outperform humanity in many ways. Their champions of intellect—men like
Socrates,PlatoandAristotle—documentedthewaytheworldworkedthroughamethodof
observationandcommonsense.
Someoftheirmoreobviouserrors,suchastheAristotelianmodelofa“Earth-centric”
universe, took many, many years to disprove. Galileo underwent torture for his sin of
creatingabetter/moreaccuratemodelofthesolarsystemthanthechurchwasawareof.
Platowasabletoprove,inhisinfamousstyleofquotingSocratesthathumansdon’t
learn. They merely remember what they knew from a previous life. It would be many
centuriesbeforeJungbegantalkingaboutthecollectiveunconsciousinasimilarwayto
explainhisobservationsaboutpeople’sinnatecapabilities.
Is human intelligence a more complex entity than the scientific study of astronomy,
physicsorchemistry?Hugeadvanceshavebeenseeninthosesciencesintheyearssince
Galileo—especially since the start of the 20th century. The composition of the atom has
beendescribedtoalevelofdetailthatishardtoimagine—letalonebelievetobetrue.The
universe has been described in terms of its visible history, its size, it age and the vast
variety of its celestial bodies. We live in a universe that exceeds the imagination of the
greatestmindsofsciencefictionbyitssheervarietyandsplendour!
Whythen,hasthestudyofintelligencebeensopooratdescribingthehumanbrain—
and the subsequent implementation of non-human intelligent machines? A most likely
reasoncomesbacktotheissueGalileohadtoovercome—thehumanmindisverypoorat
explainingideasthatcontradictourbasicbeliefs.
In the case of human beings, we seem reluctant to attribute intelligence to other
animals. Yet, it is likely to be the case that the easy things to model in an intelligent
machine will be the higher human functions. The functions of a dog: balance, climbing
anddescendingstairsonfourpointylegs,enjoyingthecompanyofhumansandlearning
tricksaresomeoftheamazinglycomplextasksthatdogsappeartodowithoutthinking.
Wedon’tusuallyattributeintelligencetodogs,andyetdogsappeartobeconscious,able
to make complex decisions over which animals are food to eat and which humans are
friends and which are enemies. If we took a dog and added the language and planning
abilityofhumans,adogwouldprobablybealsoman’sbestfriendatschool!
Weare,inmanyways,God-like(althoughmorethanahundredyearsago,Nietzche
pointedoutthatGodisdead).Whatelsedowecompareourselveswith?Althoughfewin
the scientific world today accept the full doctrines of religion, we nevertheless typically
fall back on reincarnation and the Christian beliefs of heaven and hell when our lovedonespassaway(thisistrueinAustralia—I’mlesssureofothercountries).
Thegoalofthisbookistoignorethepre-conceivedideasofthepastandlookatwhat
humans do and how we seem to do it. Why should we move on from being the most
intelligent species on the planet, to a species that can take advantage of our natural
surroundings to produce even more intelligence? In the same way that we overlook the
bestwaytorunourplanetduetopreconceivedideasandpowerstructures,weoverlook
theobviouswithmachineintelligence.Untilnow,thatis.
Whatfollowswillcovermanyoftheideasknownaboutourbrain.Howwelearn,how
wechange(unlearn),howwerepresentideasinourbrain,howourlanguageisbased,and
manyotherfactsoverlookedbymostresearchers.
T HE DEATH OF AI
Artificial Intelligence (AI to its students) has been a research area since the 1940s
during the birth of mechanical computers. Today, these mechanical computers are
commonly called computers. Although the first computers were people who manually
computed figures for companies, the computers developed in the 1940s produced the
abilitytorepresentknowledgeassymbolsinadditiontotheirnumericalrepresentations.
AIworkersbegantomakeoutrageousclaimsaboutthenewAImachinesthatwould
change every aspect of our lives in the next few years. Compare this to the time when
astronomersfirstnoticedthatthestarswerealongwayaway.Therewerenoclaimsthat
wewouldsoonbevisitingthem.Why?Justbecausetheycouldobservethemdidn’tmean
thattheyhadthetechnologytogothere.JustbecauseAIresearchershadamachinethat
couldaddandmultiplyquickly,shouldn’thaveledtotheconclusionthattheywouldsoon
haveamachinethatwillunderstandtheworldarounditthroughvision,touchorhearing.
As I stated in the assumptions: thought is not a computational process. Basing the
developmentofanintelligentmachineonaprocess—likeAI—thatdoesnotmimichow
our brain works will and has led to failure. An understanding of how our brain works
enablestheconstructionofcomponentsthatwilldothejob.Thereisnospeculation—we
knowthatthebraincandocertaintasks.Ifweproducemachinesthatdothesetasks,the
machinewillstarttobehavethewaywedesignit.
W HO DO WE MODEL ?
The first question to consider is what will make an intelligent machine? As
psychology observes how people work, and people are our best source of intelligent
behaviour, then it makes sense to use their input. Note that we will comply with the
documented observations of psychologists but not their theories. There are useful
observations made by the likes of Freud and Jung, for example. However, their theories
soundtodayliketheramblingoflunatics—inlinewithotherexamplesfromtheturnofthe
century.Similarly,philosophyprovidessomeusefulobservations.
Cognitivescienceisamulti-disciplinaryscienceintendedtoassistintheproductionof
intelligent machines. It adds the field of linguistics and neuroscience, the study of our
physical brain and nervous system and its interactions with our body. Computer science
thenallowsustomodeltheresultingconcepts—althoughinthemovefromAItomachine
intelligence,newmachinedesignsarerequiredthatdifferfromacomputer’sdesign.We
are no longer interested in modelling the human calculators adding large columns of
numbers.Wewanttoproduceamachinethatcansee,hear,speak,moveandfeel—some
ofthebasiccomponentsofhumanintelligence.
Whoelsedowemodelinthequesttoproducemachineintelligence?Therehasbeen
anexplosionofmaterialtoimprovehumanity.Therearethemanagementtextbooksthat
considerhumanbehaviour.Moreimportantlytherearethenewagethinkers.Mensuchas
AnthonyRobbinsexplaintheworkofpsychologistsandtherapiststothemasses—these
provide models and working examples of how to manipulate our brain. Our machine
intelligence has no better starting place than here. In fact, some of the difficulties in
producingintelligentmachinesinthepasthavebeenthisevidentlackofappliedresearch
material.
R OBOT P RODUCTION
Canweproduceahuman-likerobotin1998?Theanswerisno,althoughagreatmany
science-fictionwriterswouldhaveusbelieveotherwise.Canweproducearobotwiththe
capabilitiesofsimpleinsects?Againourcurrenttechnologicalcapabilitydoesnotprovide
for this. Can we produce a machine that drives a car—or reads a book and produces
commentaryonit?No.
Ihavebeenintriguedwiththeconceptofproducinguseful“computing”toolstoassist
humanitysinceatimebeforeIsawStanleyKubrik’s2001:ASpaceOdyssey(writtenby
Arthur C. Clarke). The idea of interacting with the HAL 9000 computer was quite a
pleasing concept to me, as much from the mental challenge of talking with it as to the
simplificationoftasksthatsuchacomputercouldmaketoourdailylives.
Withsuchaninterestintheidea,IbecameastudentofCognitiveSciencewiththeaim
offurtheringmyknowledgeinthefieldandcreatingsuchademonstrationsystem.After
completing my university studies, other commitments took me away from the study of
machineintelligence.
Imagine my surprise to find that little has changed, nearly 15 years later. Why has
there been little progress in machine intelligence—an area that promises so much and
indicatesgreatfinancialrewards?
The answer lies in our understanding (or lack of understanding) of two technical
challenges: How does our human vision system work and how can we understand
language?
W HY HAS PROGRESS BEEN SLOW ?
There appear to be two approaches to the challenge of machine intelligence: one
comesfromthefieldofcomputerscienceandonecomesfromthefieldsofneuroscience,
linguistics,philosophyandpsychology.
Those trained in the computer technology have been brought up to understand the
principles of computation and ordered programming to solve problems. Brute force
approacheswhereamachinerepeatedlyperformsaspecificoperationuntiltheproblemis
solved are commonplace. This approach is the counter-example of a computer that can
manipulatevisionandspeech.
Thosetrainedintheothercognitivesciencesusuallysufferfromalackofknowledge
ofhowacomputeroperates.Understandingofthebrainstructureisoflimitedassistance,
as there is not currently a good roadmap to follow from our understanding of the brain.
Turningtothemodelsofexistingcomputersandtheirassociatedprogramsagainresultsin
somebasicallynegativepremisesbeingcreated.
There are also some solid theories about language, from such scientists as Noam
Chomsky,whichprovideagoodprocessingmodeloflanguage.Sadly,thismodeldistracts
frommodelsthatprovidethesamefunction,buthavethecapabilitytogofurther.
The secret to creating a scientific advance in an area where there is clearly no road
forward requires two skills: the understanding of the existing systems without any
commitmenttothemandtheabilitytodiscardmanyofthoseideasinthequestforanew
model.
D EATH OF PROCESSING
Why are we so obsessed with processing? Of course our Von Neuman architecture
computerworksbytakinginformationfromastore(misleadinglycalled“memory”)puts
itintotheCPUregistersandthenisabletoprocessit.Thisprocessingcanbeanoperation
suchascompare,add,subtractandsoon.Itisprocessingbased!
Whywouldweassumethatourbrainprocessesanimage?Partlythereissupposition
that our brain combines images from the two eyes to form a distance measurement of
sorts.Thisenablesustohuntpreyeffectively.Butwhydoweassumethatprocessingis
involved?
What if, rather than process all the information we receive into lines, movements,
shadows,andsoon,wesimplycomparedtheimagetoallpreviouslyseenimages?
What if our brain is a parallel machine that is able to compare large numbers, vast
numbers of previously seen images and find the best matching ones in the presented
image? What if, in order to recognise a block, the computer merely compares all
previouslyseenobjectsforamatch?
Itcan’tbedone?Ifthisisso,itisonlybecausewehaven’tdesignedtherighttypeof
computers.Itwouldbefarsimplertodesignasystemtorecognisepreviouslyseenimages
than to design an image construction system—a parsing system for vision, if you will.
Although Chomsky would not like this approach, what if the computerised parsing
systems created to understand language were counterproductive to intelligent vision
progress?
D EATH OF THE P ROCESSING M ODEL
The death of the processing model can be useful here, as well. By using pattern
matching, rather than processing as in our vision system, perhaps a better approach is
possible.
Whatifwehadasystemcapableofstoringwordswithreferencestowhosaidthem
andlinkstowhattheobjectsare?Thisissimilartothelearningenvironmentofthechild.
Theeyesareabletomatchwordstoobjects.Forexample,thiscanbeseenwhenachild
locatesanobjectwhengivenitsnamebyaparent.
Now,whatifoursystemwastostoreallwordsandsentencesutteredwithreferences
to the people who said them, the way they are said, and the objects that are discussed
linkedtothewords.Thememorywouldquicklybecomearepositoryforaccesstoobjects
(vision),names(auditory),grammar(theorderinwhichthewordsareheard).Syntaxis
impliedbythemanipulationofobjectsbeinglinked.Ifthesentence,“putthehammerin
theatom”isstated,theknowledgeofthesizeoftheobjectsindicatestheissuewithit.
D OES IT ADD UP ?
Addingwiththealternativearchitectureshowssomeinsightintothemodel.Let’sadd
1 and 4. As Appendix A demonstrates, the processing model, while helpful to solve
problemsusing1950stechnology,isnolongerimportantinthequesttosolveproblemsof
addition.Simplyusingamemorysystem,suchasthatproposedwithMachineIntelligence
Memory(MIM)—wherecomponentsarelinkedtogethertoproducealarge-scalesensorylinked system providing immediate recall of linked information—enables equivalent
results to processing problems without the need for computational capability in the
machineintelligence.
Itisunlikelythatthehumanbrainhasacomputationalcircuitinanywaysimilarto
themoderncomputer,sowhyassumethatanintelligentmachinewillrequireone.
T HE M ACHINE
Whatdoesanintelligentmachinecomprise?Clearlytheremustbethebasicsensesof
ahuman.Thestudyofphilosophyhashighlightedthefactthattheworldweexperience
throughoursenses,theworldofphenomenology,isonethathumanscaneasilytalkabout
usingourlanguagecapability.
S ENSES
Thereareanumberofhumansensesthatwillprovidethebasisforlearning.Learning
by example is one of the easiest ways of enabling a machine to work in our world.
Unfortunately,today’scomputersdon’tlearnbyexample.Thishasresultedinthetedious
processofattemptingtoprogramwhatweobserve.
For example, have you ever attempted to explain to someone, who is blind, simple
instructionsondealingwiththephysicalworld?“Canyoupleasewalkovertothemiddle
of the room and pick up that piece of paper?” you ask. “No, the middle of the room,
behindyou,yes.No,totheleft,notyourleft,myleft.That’sitthreemoresteps—okstop.
Itisjustinfrontofyou—noonthefloorbelowyou,infrontofyourfeet…”
You get the point—the information required to verbally describe a visual image is
large—andthemessagewemustsendisneithersimple,norarewewellpracticedatsuch
long-windeddescription.Infact,iflanguagewereintendedtodescribesuchvisualthings,
wewouldnodoubthavewordsfor“twostepsforwardontheground”and“behindyouat
waistlevelthreepacesaway”.
Therearemanyhumansenses—theobviousonesincludevision,hearing,touch,taste,
smell,andbalance.Wealsohaveadditional“senses”thatarefacilitatedbythekeysenses.
Wehavedepthperceptionaspartofourvisualcapability,wehaveanideaofwhereour
limbsareatanymomentthroughourtouchsense,wecansenseaccelerationthroughour
senseofbalanceandwecandetectwordsspokentousaspartofoursenseofhearing.In
fact, our basic transducers—our I/O sensors to use some computer jargon—are able to
providesomeveryusefulcapabilitywhencombinedinourbrain.
Howdoweorganiseourintelligentmachinetodeveloptheseothercapabilities?
M ACHINE I NTELLIGENCE M EMORY (MIM)
Machine Intelligence Memory (MIM) differs from the so-called memory used in
computers. Memory in a computer provides the ability for a CPU to take out for
examination a unit of data—usually only a few characters in length—to process or
compare. While this is handy for the task of adding up sums of numbers, it is a foolish
designforcomparingonedigitisedimagewithseveralthousandotherimages.
MIMhastwokeytaskstoperformandthesetasksandthefunctionperformedenable
a machine to become intelligent in real time. It is possible to produce an intelligent
machine without MIM, however a machine that takes six hours to respond is hardly
intelligentinmostpeople’seyes.Thetwotasksareasfollows:
1. To identify and store new and recurring patterns in the information being
received.
2. Torecognisepatternspreviouslystored.
These two steps are so important for learning that machine intelligence is hard to
imaginewithoutit.Why?Becauseifthesebasicelementscanidentifyandmatchpatterns
in their experience, MIM can perform some amazing feats that explain many
psychological,linguisticandneuroscientificobservations!
It is important to consider that in itself, this process is not intelligent. It is merely a
mechanical means for storing information without need of consideration. That is, by
findingapatternintheexternalworld,theinformationneededtoidentifyitasapattern
againinthefutureisstored.
O UR B RAIN ’ S C ONSTRUCTION (MI CONSTRUCTION )
Our system will use what I call machine intelligence (MI) To construct our MI
machine,weconnectsensestoMIM,individually(seeFigure1).Althoughinitiallythere
maybeaneedtoincludesomebasiccomponentsintheseMIMstodetectkeyitems,ina
similarwaytothatusedbythehumaneyeandvisualprocessingcentresinthebrain,the
MIMconceptallowsforthistonaturallyoccur.
Figure1:Thesenseslinktotheir
ownpatterns—andthentoanoverallpatterndevice.Forexample,burnttoastis
distinguishedfromtoastwithvegemiteduetoitscolour,smell,tasteandtexture.
Atthispointitisimportanttobegintolookforhigherlevelsofpatterns.Amachine
that recognises patterns in the external world is not intelligent. MIM must additionally
monitorthematchesbeingmadebetweentheindividualsenses.Thisissimilartotheway
that our brain forms associations with objects observed at a similar point in time. The
typesofpatternsthatcanbemadethiswayinclude:
1. Thelinkbetweenthesmellofanoilyragandthelookofit;
2. Thelinkbetweenthesoundofagunfiring,theflash fromthemuzzleandthe
feeloftherecoilforce;
3. Thelinkbetweenawordandthesightofanobject;and
4. Thelinkbetweenthetopviewofanobject,theleftviewandthebottomview.
Theselinksprovideforsomeusefulcapabilitiestobemade—andlearningbecomesa
question of experience. As experiences are made using multi-sensory input, patterns are
matchedthatformwhatisthebasisforobjectrecognitionandreal-worldknowledge.
Itappearsthathumansaredrivenbytwoforcesandhavecertaincapabilities.Humans
are driven by their ability to match objects and experiences previously learned. And
humans associate between certain events that occur in close time proximity. Our brain
usestheobjectsandassociationsforthebasisofconversationandaction.Ourbrainisable
to directly locate fragments of sensory experience and through association change the
currentstateofmind.
Simplyput,humansuseassociationsandanorderedcollectionofobjectstospeakand
move quickly—without thinking. In other words, rather than combining information
throughaprocessofanalysis,humanshavepre-preparedprogramswhicharewiredinto
ourbrains.Theseprogramsaresimplyrun—whetheritbetospeakortothrowarockata
rabbitinordertoreceiveahigh-proteindinner.
MIO PERATIONS
When the intelligent machine is in operation, the MIM memory will automatically
start detecting and storing patterns. At a higher level of MIM, one that monitors many
sensesforexample,theMIMwillstorelinks(patternsdetected)betweeneventswithout
theneedforanalysisorthought.Ifthoughtisrequiredfordeterminingwhattolink,the
age old issue would be raised—who thinks for the brain’s thinker? The homunculus
returns. The model presented here—the one that has MIMs to remember what has
happened, is a model that does not require thought. The system just automatically
rememberspatternsbystoringthem.
SLEEP
For the model proposed, the system builds up a large number of similar database
objects.Tooptimisethesystemandavoidtoomuchdatabeingstoredunnecessarily,the
system must be shut down on occasion in order to compare recently stored objects and
determinewhethertheyshouldbestoredinthelongertermordiscarded.Inotherwords,
thereisbenefitinaperiodofinactivity,similartosleep,inordertooptimisethesystem
both in terms of future performance by discarding similar objects and in terms of total
storagecapacityrequired.
In the human and mammalian example, the system is shut down for a period called
sleeptime.Duringthistime,thereareanumberofactivitiestakingplace,suchasdreams,
REMsleepandsoon.
Wedonotknowwhyhumansdream;however,wedoknowthatmachineintelligence
will need a period of inactivity similar to dreams. Interruption of the consolidation of
memory may well leave vivid traces that cannot be attributable to experience. It is
interestingtonotethatneurosurgeonshaveatechniquetodeterminewhattissuetoremove
insurgerythroughaprocessofbrainstimulation.Intheprocess,thesurgeonwillstimulate
the brain with a probe. When the probe affects a specific part of the cortex, patients
experiencevividmemoriesindicatingthelinkagesbetweenthatpartofthebrainandthe
experiences(Hume’sideas)thatwerestoredafterbeingperceivedasimpressions.
C OMPARISON TO D AVID H UME ’ S MODEL
DavidHumearguedthatthebraintakesininformationdirectlyfromthesenses.That
informationisclearasitisreceiveddirectlyfromthesenses—hecalledthisdirectsensory
experienceanimpression.
Oncetheseimpressionsarestoredinthebrain,theyarelessclearandhecalledthese
memoriesideas.Asrecalltakesplace,ideascombinewithotherstoproducenewoptions.
Humeindicatedthatcomplexideas—thosecomprisingmanysimpleideas—arevalidonly
iftheycorrespondtoimpressions.Ifthebrainneverexperiencedacomplexidea,butonly
experienced a series of simple ideas, then the complex idea is false and should be
committedtotheflames.
I will use the terminology of Hume for impressions and ideas to ensure consistency
withphilosophy.
P ATTERN MATCHING , LEARNING AND UNLEARNING
Thequestionofthebrain’spatternmatchingcapabilityisclear.Ifahumanwalksinto
aroom,thereisanalmostinstantaneousrecognitionoftheobjectsaround.Thepatternsof
avisualenvironmentareeasyforthebraintorecognise,althoughtherecallofthenames
is clearly a separate process. Pattern matching is recognition, not recall. The computer
gamethatdrawsa3-Denvironmentonascreenforinteractionisnotmachineintelligence
—MIduplicatesintelligentbehaviour.Itdoesn’tcreateimages(recallofMIM)forvideo
projectionanymorethanahumancanprojectamoviefromhereyes.
Learningistheprocessofmatchingandstoringpatterns.Therecognitionisgearedup
tocombinethesenses—thesoundofafireislinkedtothesightofafireandislinkedto
thesmellofafire.Themoresensestherearethatareconnectedtoanobject,theeasier
recognitionwillbeastherearemorepathways(links)totheobject.
Whybasemachineintelligenceonthisidea?Becausepeoplerelyonassociationandit
isatechniquethatenablesamachineto“learn”.Computersbecomeintelligentmachines
by learning to connect experiences—not by clever human programmers learning how to
write complex programs to describe a machine’s version of reality. Of course, there is
more to human memory than just recognition, and that will be explained soon. Without
thisrecognitioncapabilityinourMachineIntelligence,thetaskbecomesdifficult,indeed.
Unlearning.Whatdoesthatmean?Welearnbylinkingtogetherobjectsthathavebeen
recognised—these objects can be from any of the senses. This follows from childhood
observations,wherechildrenlearnthebasicsoftheenvironment—blocks,toycars,puppy
dogs,icecubes.Eachisexploredintermsoftaste,viewpoints,smell,weight,temperature,
colour, texture. Who hasn’t seen a child pick up a stick from a garden and put it in her
mouth? These multi-sensory experiences enable the associations with the object to
produceausefulmemoryforfuturereference.
Unlearning is the process of disconnecting those associations. Unlearning is one of
thoseskillshumansdonotlearntodo(exceptincertainstressfulsituations).Withoutan
ability to unlearn, prejudices are formed and remain—despite information that is to the
contrary. Without the ability to unlearn, childhood problems remain throughout life.
Without the ability to unlearn, we all exhibit irrational behaviour at times for no clear
reason. Without the ability to unlearn, we are all distinctly human, and all distinctly
intelligent.
Ourcomplexitycanstillbeexplainedintermsofasimplemodel.Thismodel,through
theinteractionwithitscomponents,enablesthecomplexbehaviourseeninhumans—the
behaviour which is unique to each individual based on her experience and the way in
whichtheelementsareconnectedinthebrain!
M ORE COMPLEX SENSES
The sense of touch has a number of capabilities—temperature, texture, vibration,
pressure, movement, duration, steady-intermittent, intensity, weight, density, location…
Clearly, each of our senses is a summary description of a number of more specific
attributes.Eachsensealsodetectspatternsatdifferentlevels—thisabilityisnotsomething
humansconcentrateon.Itjusthappensasaresultofthewiringofourbrain.
Is this all there is? A collection of senses connected to a group of pattern matching
machines?Ofcoursenot!TheremustbethecapabilitytoconnecttheMIMsthatmatch
differentattributestogethertoformasinglesensetoidentifyobjects.Similarly,thehigher
levelMIMthatfindspatternsintheattributeMIMscannotfunctioninisolation.
These attribute MIMs are consolidated within the sense to identify objects. Higher
level MIMs again connect objects together to identify the different sensory input in one
place.Thisisfinefortheidentificationofsingleobjectsfromtheirconstituentattributes.
Keep in mind that this process is automatic—MI must simply connect patterns detected
from lower level MIMs to the higher level. Our brain appears to have the capability to
connectmanyotheremotionalattributeswithobjectsorsequentialprocedures.Thisisalso
automatic and such people as Anthony Robbins explain what techniques can be used to
unlearn these unsupportive links and replace them with supportive ones through such
psychologicaltechniquesasNeuro-LinguisticProgramming,NLP.
Butwait,there’smoretothesensesthanmeetstheeye.Thisusefulcapabilitytodetect
patterns from our senses and connect them to form objects has a useful offshoot—
language.
The capability of a sense isn’t simply what we experience—it is also what we
concludefromit.Theseconclusionsincludethebasisforlanguage,inference,logicandso
on.
L ANGUAGE
Language is a special feature of higher level pattern matching. By the process of
recognition of word sounds detected, which automatically link to the visual, auditory,
kinaesthetic, olfactory, or gustatory objects, the sequences of words are stored by the
brain.ThepatternsinwordusearedetectedinatleasttwoareasbyMIMs.
Therearepatternsofwordusagethatrelatestotheorderinwhichwordsarespoken.
Theorderensuresthatthesamemeaningcanbeattributedthenexttimethesameword
orderisused.Thereisanimportantdifferenceinthegrammaticalmeaningof:
1. Hithim.
2. Himhit.
Most English speakers will understand both sequences. ‘Hit him’ is an order to
probablecruelty.Thelatter,althoughpoorEnglishusage,meansthatthemanhasorwill
hit. The point is that the grammar of language is important and is a product of pattern
matching.Inthiscase,thepatternsarethewordsequencesdetected—automatically.
AMIMmonitoringauditoryinputwillresultinpatternsforhearingandwillgenerate
the capacity to recognise good grammar—meaning whatever is heard is, by definition,
goodgrammar—atleastinitiallywithouttheabilitytounlearncomingintoplay.
Ofcoursegrammarisimportant,butasthehugenumberofexamplesdemonstrating
thatwordorderdoesnotuniquelydefinemeaning,moreisnecessary.Noticethataswords
are recognised by the grammar-matching machine, that there are links to the objects
referenced themselves. These links produce patterns that a MIM can monitor. The
sequencesinthiscaseprovideadifferentpattern—apatternofobjectrepresentationand
themanipulationofobjects.ThisMIM,whichisoftenreferredtoasthedeepstructuresby
linguists such as Chomsky, produces the effect of an inner world that can be
communicatedbetweenindividualsthroughlanguage.
Let’s explain this another way. Language is triggering a sequence of objects in the
brain—these create a pattern that represents an artificial environment. This environment
conveysamessageofactionorsimpledescription.Theprocessoflearning,MIMpattern
detection,enablessequencestobefound.
Of course we all know that sequences of grammar can never be complete since
grammarisaninfinitelyvaryingchoice.Rememberhowever,wehavethelinksbetween
objectsatthedeeperlevel(notsimplegrammar).NoamChomsky,thewell-knownlinguist
toldussoandabasicconsiderationoflanguagebacksthisup.Thedeeperlevelprovides
generalisation—patternsofobjectsexistinthisdeeperlevel.Forexample,acatandadog
are both pets, potentially. In order to know that fact, we have a link between them—or
rather,aMIMhasnoticedthepatternthatmanydogsarepets—sothegeneralisationthat
maybestoredisthatdogsarepets.
Through a process of generalisation, objects that represent the act of playing games
oftenfollowobjectsthatrepresentpets.Backintheworldofgrammar,theactofplaying
gamesareacollectionofphrases.Phrases?
Patternsareimportantatmorelevelsthansimplegrammarandthedeeperlevel,called
(say)syntax.Therearecollectionsofsentencesthatformphrases—aMIMmonitorsthose.
Similarly,aMIMmonitorsstories—conversations.TheseMIMsenablepatternsinstories
to be generalised to further understand the world. By knowing what happened in a
particularstory,similarsequencescanbeputintoactioninlife.Welearnfromexample
andapplytheexamplesfrequentlyandbydefaultasthealternativeisgenerallythought,a
processofworkavoidedbythebrain,ifatallpossible.
Language is an interesting example of the complexity of linkages available in the
human brain. The lack of linkages, the lack of memory and the lack of performance of
slowmodern-daycomputersresultsinthepoorresultofacomputerinreal-worldhuman
intelligenceprocessing.LanguageisthedriverforthecreationofMI.
LANGUAGEEXAMPLE
Exampleofasimplelanguagestructurewillhelptounderstandtherequirementsofa
functioning brain. Let’s consider the sentence: ” The cat sat on the mat.” It should be a
simpleexercisetomapthisintoitscomponentmeaning.Shouldn’tit?
LANGUAGEUNDERSTANDING
Languageunderstandinghassomedifficultchallenges,indeed.Therearehundredsof
rulesofgrammar–manyaredifficulttowritedownandonlythelargesttomesarecapable
ofwritingtheentiregrammarforEnglishintobookform.
Sadly,thisdoesn’tassistinthedevelopmentofcomputerlanguageunderstanding,asa
language parser merely breaks a sentence into its component parts. If the sentence is
incompleteorunheard,thenthesystemfailsutterly.Itiscommontohearquotesthatmost
humans only hear a small part of what is said to them – yet understanding can be quite
highdespitethesmallnumberofwordsheard.
Thedeepermeaningofwordsmustbetakenintoaccountinordertoensurethatthe
sentences said or written are possible in the real world. Ah, this leads to real world
understandingandknowledge.Anotherchallenge!Orisit?
To process natural language according to the textbooks is a multi-step and complex
procedure. Luckily a computer can do this with recursive calls! There is a considerable
amount of complexity in grammar, much of this is caused by the nature of word
combinations used in history. Perhaps, as Chomsky claims, this is due to the deep
structuresoflanguageandauniversalgrammar.
Perhapsallthisprocessingrequiredinordertounderstandlanguagecanbeunderstood
a different way? Perhaps there is a method similar to our first technique that can be
employed.
HUTCHENS’LOEBNERPRIZEPROGRAM
JasonHutchensisaresearcherattheUniversityofWesternAustralia.Asaparticipant
to the Loebner prize, the contest to compete to match the Turing Test, Jason’s program
wassuccessfuloneyear.
The program uses a similar basis as the MIM model—in this case a model called a
‘third-orderMarkovmodelonthewordlevel’.Theprogrameffectivelytakesdiscussions
with people through the keyboard, and adds the word links to its database. When the
program is building a response, it uses previously experienced word sequences. These
wordsequencesarebuilttousetheleast-probabilityresponse,inordertocreatetheleast
likely combinations. The conversations are hard to follow, although they follow
grammaticalrules,andarethereforenativelanguagesentences.
It is interesting that the resulting conversation is better than many other examples
peopleareabletoproduce.Let’sexaminehowthismodelrelatestotheMIMmodel.
In the case of MIMs, word sequences are monitored and linked together. Of course,
the MIMs also link the other components together as well, such as visual data, auditory
data, kinaesthetic data, and so on. In this case, the MIM is limited to only one sense,
writtencodedwords(bluntly,itisblind,deafandinsensitive).Nevertheless,theprogram
isabletocapturethegrammaticalstructureoflanguage.
This is a small and limited application of the MIM theory, and its success is initial
supportforthecomprehensiveMIMmodel.
V ISION S YSTEM
The human vision system performs a simple task – to identify to the owner what is
goingonaroundhimorherfromadistanceusingthereflectedlightfromvariousobjects.
Emulatingthisonacomputerhasprovendifficult.
Thetrickappearstobe,basedonthewealthofcomputersciencetextbookswritten,to
solve the puzzle of how the brain makes so many calculations in less than a second. In
fact, in around the time it takes for the nerve impulses to travel through 8 neuron
groupings,wecanrecogniseascene.Thistakesaroundaquarterofasecond.
For a sophisticated computer, taking into account the lines we see, the shadows, the
colours,theambientlight,theunusualangleatwhichweseeanobjectandsoon,thereis
a heck of a lot of calculation required to compute what objects we are seeing. Further,
thereisaheckofalotmoreinformationweneedtocompareinordertounderstandwhat
thephysicalrelationshipsarebetweentheobjects–canaballholdupaglass–orarewe
seeinganopticalillusion?Givenabout6hours,agoodcomputercandeterminetosome
degreewhatthepicturerepresents.
Many computer textbooks tell us that the computation that is required by our serial
processing computer must somehow convert images. This conversion duplicates the
paralleltechniqueusedbyourbraintounderstandimages.Buthowdoesthebrainwork?
Theprocessingmustbedifficultwithmorethan1,000,000inputsfromourretina.
RECOGNITIONOFSPELLING
Thetaskofrecognisingspellingisonethathascausedmuchconfusion.Howdoesthe
MIMmodelexplaintheissueofspellingrecognition?Infact,somepeoplehavetheability
to recognise whether a word is correctly spelled, despite the fact they cannot spell the
wordthemselves!Theissueofrecognitionversusrecallisanimportantone.
DavidHumespokeofimpressionsbeingthedirectsensoryexperience(theeffectof
the transducers in the body sending signals to the body’s nervous system). Ideas are
further defined as the recollection of impressions—they are less real/strong than
impressions,andthebrainmanipulatestheseinextremelyfasttime.
According to Hume, therefore, the recognition task is one in which direct sensory
details are compared with information previously stored—i.e. with ideas. In the case of
ourMIMmodel,theMIMscontaintheideascapturedduringpatterndetectionovertime.
Asnewimpressionsaremade,theyarecomparedwiththeexistingideas.Newideasare
formed either immediately or during a period of inactivity of the system when large
volumesofmaterialcanbeeliminatedorcompressed.
Thehumanbrainismuchbetteratmemoryrecallwhenunusualobjectsarecombined
with multi-sensory experiences, rather than single-sensory information. How does this
relatetotheissueofspelling?
Thereareanumberoflevelsofpatternmatchingrequiredtounderstandspelling.Ona
pageofwrittentext,therearelettersdrawn,therearegroupsoflettersformingwordsand
groups of words forming sentences. There are higher levels of categorisation leading
finallytoacompletebook/letter/document.Tounderstandspelling,thebrainmustbeable
toidentifyalltheselevelsofobject.
Intermsofthespecificwordsinthesentences,thereissomerelieffromthedifficulty
of reading individual letters, as the words must be used in context and following a
grammar.
MIMsmanagethisasfollows:thelettersarepatternsstoredastheMIlearnstowrite.
Theprocessoflearningsendsthemulti-sensoryexperiencetothemovement,visual,and
kinaesthetic part of the MIM. Reading requires the impressions on the page to be
convertedintotheimagesthatcompriseastory.
Afewlettersinmostwordsissufficienttorecogniseasingleword.
Thisisagreatadvanceoverthepreviousmodel—asnolongerdoweneedtorelyon
eachandeverylettertocreatemeaning.
RECOGNITIONOFWORDS
Therecognitionofwordsiscriticaltosupportanintelligentmachine.
RECOGNITIONOFFACES
The recognition of faces is something that humans do remarkably accurately.
Although people can forget the name of a person, they are able to recognise faces very
quickly.TheMIMmodelrequirestwosteps,thatprobablyrequiretimetocomplete—first
theimagemustbestoredthenoncethereisanobjectdefinedfortheimage,afurtherlink
tothesoundofthename,thespellingandsoforthcanbecreated.
Howdowerecogniseaface?TheMIMmodelassumesthatitisabletodetectpatterns
inthesensoryinformationpresented.Thequestionastohowthatinformationispresented
is critical for the success of the pattern-matching engine. If the MIM is able to quickly
detecttheface,usingaseriesofallpreviouslyseenfaces,thentheprocessofpullingout
theappropriateonesortheappropriatesub-selectionoffacesenablesothercontextualdata
toprovideahigh-quality,high-reliabilityfit.Providedtheinformationthatcannotbetrue
is eliminated, the search volume is significantly reduced to the point where detailed
statisticalevaluationcanbemade.
Visual recognition of faces is therefore simple to implement with the MIM model,
providedthatitisnotlimitedtosimplytheinformationforthevisualsense.Humansrely
on all senses, and for example, how often can a man recognise his girlfriend by her
perfumealone?
H UMAN E XAMPLES :P HYSIOLOGY ,P SYCHOLOGY &
P HILOSOPHY
Any brain theory needs to explain observation. That’s what science is about:
explainingobservations,predictingoutcomesandenablingtechnologytoexploitit.This
section looks at a variety of human observations and explains them in terms of brain
theory based on intelligent memory, rather than on the computer model of memory
interactingwithahuman-writtenprogram.Comparetheseexplanationstocontrasttoday’s
approachwiththealternative.
Bytheway,whilesomehavetheorizedthatmachinescouldwritetheirownprograms,
in practice that has not happened in the same way that AI has not happened. Having a
machinethatlearnshowtoworkintheworld,ashumanbrainsdo,isimportanttoremove
theneedforprogrammers.
P HYSIOLOGY
Physiology is a term used by the motivational speaker, Anthony Robbins, among
many others. Anthony describes the effect of the human emotional state as influencing
human behaviour. By being in the appropriate emotional state, you are able to perform
feats not possible in other emotional states. For example, by being in an extremely
positiveandconfident,Anthony’sstudentscanwalkoverhotcoals.
This observation is explained in terms of the MIM model as follows: the MIMs are
constantly capturing information about the environment—linking visual objects to
auditoryobjects,togustatoryobjects,tofeelings—infacttoanyobjectcurrentlyactiveat
thesametime.
AsMIMsarelinkingactualsensoryinformationtogether(Humecalledthesesensory
experiences“impressions”),thebrainisabletolearnthatanappleissweet,arosesmells
niceandapillowissoft,nottomentionthelanguagethatidentifiestheseobjectsthrougha
linkageprocess.ButHumealsoidentifiedthatthebrainhasarecollectioncapability.He
calledthisability“ideas.”Ideasaresimilartoimpressions,onlyweaker.
MIMs, over time, store impressions for future use—the data that is stored becomes
Hume’sideas.TheywilllinkwithotherideasinMIMsthroughtheautomaticprocessthat
is designed into the MIM. Should the intelligent machine be in an emotional state of
excitement, the ideas linked at that time will be connected to that emotion. Later, if the
machineintelligenceisinastateofdespair,otherideaswillbelinked.Itislikelythatthe
events will be quite different in the different environments, as the MIMs will link
activitiesthathappenwhentheappropriateemotionalstateisheld.
The point is humans are often compelled to act in inappropriate ways due to their
emotionalstate.Inthiscase,asMIMsenabletheactionsthatfittheinput—andtheinput
maywellincludetheMIMconditionofemotionaldespair—themostlikelybehaviourto
produceistheonepickedupbytheMIMsinthestateofdespair.
F REUD
SigmundFreudisoneofthebetterknownscientistsofthenineteenthcentury.Freud
made many observations of a certain type of patient and identified neuroses. Whether
neurosesareanactualthing,orifitisanothertypeofmind/epicycle,isn’timportant.What
is important is that he made a number of observations about human behaviour that any
modelofintelligencemustalsoexplaininordertobeconsistent.
Remember that Freud put forward a number of statements to describe the human
brain.Forexample,thedescription,“unconscious”describestheobjectiveandsubjective
human experience of the “ideas” that comprise “thought”. The question is, however, is
thereanunconscious,orsimplyaneffectcausedbythedesignofthehumanbrain?Isn’tis
equallyvalidtoidentifytheexperienceasthatcausedbythemanylinkagesexistinginthe
brainwhenexperienceisbuiltup?
For example, when a child is hit after opening his parents’ bedroom door, his brain
mayhavealinkcreatedbetweenthepainofthehitandtheopeningofthedoor,through
theprocessofassociation.Later,whentheboyappearsonanationalgameshowandhas
to choose between a door and a box, he chooses the box. This can be because his
“unconsciousbelievesdoorsarebestleftclosed”ormoresimply,hehasmorepainlinked
toopeningthedoorthantoopeningthebox.
Psychoanalysismaybeabletoexploretheboy’sbrain’slinkagestodiscoverthathe
hadthisbadexperiencewithhismotherandfather,butreallythereasonforhissubsequent
actionscanbeexplainedinthesimpletermsofthestrongerfeelingslinkedtothedoor.
ThepointisthatMIMsenablethesearchingofinformationtobebroughtforwardas
possible solutions. Consider the human brain, an organ that has not been specifically
designed and is therefore imperfect. It is reasonable to assume that the feedback that is
subjectively experienced is the result of MIM-like searching of memory, rather than
another component of the brain—called the unconscious, for example, which has many
other meanings given over time. The unconscious is a misleading, incompletely defined
termandmustbeignored.
It was highlighted earlier in the review of language that language is built up from a
group of pattern matching systems. Grammar is generated by following the patterns
created by sequences of words. Provided words occur with some frequency, the brain
generalises that the words necessarily follow that sequence. At the same time that the
sequences of words are generated, links are also created between the various sensory
objects.Forexample,thesentence“Thedogsatonthemat”hasasequenceofwordsthat
followsthehumangrammarforEnglish.Theprocessoflearningthissentencealsohasa
linkofavastnumberofdogsinasittingposition(visual)withavastnumberofobjects
thatarefloormats(visual).Notethatthereisahugeamountofadditionaldetailavailable
fromthissentencebasedonpreviousexperience.Forexample,thedogimageislinkedto
specific dogs, their smell, their behaviours, experiences with the emotional attachment,
cartoondogs,howtheyact,whattheysoundlikeandsoforth.Thelanguageisindeedrich
duetothebrain’samazingnumberofavailablelinkages.
Freud identified parapraxis—a slip of the tongue or pen. These so called Freudian
slipsallowsomeonetosaywhattheyarethinking,despitethefactthatitisundesirableto
sayso.Howdoesthelanguagemodeladdressthisfact?
Consider the parapraxis described in Sophie’sWorld where a worker is toasting his
boss(whomhethinksisaswine).Hesays:“Here’stotheswine!”Thiswasnotwhatthe
workermeanttosay.
How does the language model deal with this? Language verbalisation requires the
patternscreatedthroughtheprocessoflearningtobeproducedbackwards.Thatis,rather
than hearing words, linking them to their meaning—meaning is created and linked to
wordsinthegrammar.
Asthebrainisabletoproducespeechwithoutin-depththought(whateverthoughtis),
thegenerationofwordsforatoastfollowsapathlikethis.Firsttheenvironmentlimitsthe
typesofsentencesavailabletobeusedtoasmallselectionofformalphrases.Oneofthese
phrasesis“Here’stoX”whereXisavastarrayofoptionsfrommemorysuchas:
Charlie,theworld’sbestsoccercoach.
Us,mayweliveinpeaceandharmony
Stalin,themanwhofreedusfromslavery.
Theexamplesgoonandonfromourlifetimesupplyofexperiencesandlinkstoother
experiencesthatcouldbehelpfulshouldanimmediateanswernotspringtomind(ifone
exists).
SothequestionishowtofillinX.Theworkerhasthefirstofthewordscompletedby
followingtheflowofthestoredgrammar(thepreviouspattern).Nextadescriptionofthe
personbeingtoastedisrequiredperpreviousexamples—theautomaticselectionismade
withoutneedfordeliberationandthustheswinepopsout!
There is no need to postulate complex, or metaphysical explanations to this
observation.Apattern-matchingmachineismorethancapableofdoingthisaction.
ConsiderFreud’sdeepermodels.Freudwroteoftheconsciousasbeingthatwhichwe
focus on, the preconscious that which we can recall if we try, and the unconscious, that
whichwecannotaccessbecauseamechanismtorepresstheideahasstoppeddirectaccess
toit.
Freuddevelopedthismodelbasedonhisobservationsofpatientswhorepresenteda
partofsocietynotnormallyclassedasabnormal.HowdoestheexplanationfromFreudfit
intotheMIMmodel?
Clearly, as information is fed into the system, patterns are stored. The process of
gathering information is fed into a combining part of the brain—as mentioned even a
reptilerequiresaunifiedviewoftheworldinordertoadoptquicklytotheenvironmentto
survive. As the combining part of the brain processes information, it is stored in the
memory—orinthecaseofourmachineintelligence,inMIMs.
CanweexplainFreud’stheorybetterbyusingMIMtheory?
WhatiftheinformationavailabletothereptilianbrainthroughimpressionsisFreud’s
conscious?Ananimalactingasasingleentityisimportanttosurvival,asthosehappyto
loselimbswilllikelydiewhenattacked.Theconsciousisthenanevolutionaryadvantage
becauseeachbrainconnectstheanimaltoasingleworldview.
Similarly, the preconscious and unconscious are both MIM details in that the
consciouscanbetheactivesetofpatternsatapointintime,whichtheMIMsassociations
arenotactive,butconnected.ProvidedtheinformationisavailableintheMIMs,itcanbe
broughttothesurfaceasanactivememory.
MIMs contain links to many other areas. For example, the association of a woman,
links to the association of your mother, which links to the association of your father.
Strongassociationsarenevermorethananactivationaway.
To use this information, it must be identified as a good fit for the problem under
revieworthebrainwouldneversolveproblems.Forrecognitionofmemories,information
must be fed through a similar system to the one that experienced it in the first place,
becauseitwouldotherwiseneedsometypeofencodingtorepresenttheoriginalsensory
experiences.Memoriesbasedontheactualphysicalsourceareeasiertoimaginethanone
convertedintoamemorythroughsomekindofcomplexalgorithmanddecoder.
RATMAN
It is interesting that some of the famous theories of Sigmund Freud centre on the
experiences of the so-called “rat man”. The rat man heard of a torture involving rats,
wheretheygnawtheirwayoutthoughthevictim’sbody.
Freud identified that the rat man had a sexual experience with his governess at a
young age, and that through that experience, he associated fear of his father through
perceived punishment and hostility. Freud worked with the rat man for 11 months to
furtherunderstandhisintricatelinkagesofmemories.Asaresult,hecuredtheratman’s
neuroses,byexplainingtheratman’sirrationalreasonsforfeelingthewayhedidabout
somethings.
Freudbringshistheoriestoplayinordertoexplainthemeaningtheratmanassociates
withhismemories.
In terms of the MIM theory, all existing memories are the basis for new memories.
Only when there is no match in the database, or when the result of the memory search
conflictswithotherknowledge/information,doesaneedtodetectnewpatternscomeinto
play.
Inthecaseoftheratman,hispreviousexperiencesresultinaccessesofonepartofhis
memory (such as memory of his lady) does an association come into play—fear for her
safety.ThetraceofassociationsthatconnectsthetwomemorieswasFreud’spsychology
andthebasisformuchofhistheories.
If children associate memories of their father with punishment, and later in life
associatesomeothermemorywiththeirfather,therewillbealinktothepunishmentand
thefeelingssurroundingit.
Another of Freud’s founding moments came in the work of his colleague, Josef
Breuer. In the case of Anna O, Josef talked through Anna’s previous experiences in an
attempttocureherfromparalysis,hallucinations,andothernervousconditions.Through
the process of talking, Anna was able to recall events that initially linked together
memoriesthatcausedherundesirableconsequences.Anexamplewasthesightofadog
drinkingfromaglasssickenedAnna.Later,shebecamehydrophobic,andcouldnotdrink
untilthepreviousmemorywasexposed.
In terms of the MIM model, the associations between memories are for the benefit of
recognition, not for recall in general. So should a machine build up memories such as
Anna, a memory may trigger a stronger association with a feeling, for example. If the
feeling is one of repulsion, it is unlikely that the MIM’s controlling element will take
action to create that event, unless there is an alternative action that has a worse feeling
associatedwithit.ThatdescribesAnna’sproblem,andisnomorethantheapplicationof
linkages between memories. The theory of Freud is one based on his dealings with
neurotics,howevertheworldhasmoreextremecasestoconsider.CarlJunglookedinto
thosecases.
C ARL J UNG
JungcanbecharacterisedasoneofFreud’sdiscipleswhoexpandedonFreud’snarrow
definition of psychology and added areas which met his greatly expanded range of
observation.AsJungexperiencedpatientsinafarmoreadvancedstateofdysfunctionality
(he worked in insane asylums), his observations expanded his theory to include such
people.
Oneofhisthemesisthatofthearchetype—thedefiningforcethatcharacterisesour
individualandourcollectiveunconscious.Thearchetypesinclude:themother,thefather,
thehero,thewiseoldman,etc.etc.
HowdoestheMIMmodelexplaintheobservationofJung?
ThemodelisbasedonMIMsdetectingpatternsintheworld.Asachildgrowsup,he
or she notices people, what they do and so on. Some of these people fit into categories
suchasthosementionedabove.Yourmother,orthepersonactingasyourmother,hasa
setofcharacteristics.Somethingswillorwon’tbedoneforthechild.Asstoriesofother
livesareconveyed,theywillincludedescriptionsofotherpeople’smothers,theirwayof
behavingandsoforth.
TheMIMs,asapatternmatchingsystem,willhaveavastamountofdetailaboutthe
mother figure. Through the various linkages that have developed over time, it will be
knownthatthemotheris(typically)onewhowilltakerisksforherchildren,acook,the
keeperofthehouse,theauthoritarianfigureforyoungchildren,theonewhotakescareof
daddy,andmanyotherthings.Throughtheprocessofbuildinguptheknowledgebaseof
themother,asetofattributeswillbeavailable.Theseattributescanbecalledanarchetype
—or alternatively as the concept applies to most other objects known in detail, the
attributesaremerelythat—attributes.
Fromthedawnofphilosophy,archetypeshavebeenakeytalkingpoint—theMIMisa
waytoenablethatprocesstoautomaticallygenerateitself.
JUNG’SFREEASSOCIATION
CarlJungexperiencedtheproblemsthatexistinhumansinafarmoreextremeway
thanFreud.Again,whileFreudwastalkingwithhousewivesfromwealthyfamilies,Jung
was working in asylums with far more disturbed people. There is a great difference
between a housewife feeling depressed and unfulfilled and a person who takes every
opportunitytomutilatetheirbody.
Freud related his observations to a number of characteristics that fit his model of
humanpsychology.
Jungcreatedatooltoassistwithunderstandingthesourceofaperson’sproblemusing
freeassociation.Infreeassociation,thepsychologistsayswordsandthepatientresponds
with their first association. Through this process, the psychologist is able to understand
somethingaboutthepatientandenablea“healing”processtotakeplace.
Althoughahealingprocessmaybenomorethanchangingtheperson’sassociationto
somethingmoreuseful,theidentificationofthememorycausingtheproblemisvital.
Howdoesthemodelpresentedheredealwiththisobservation?WhatisJunggetting
atwhenheislookingintotheassociations?Asthebrainisconstantlycreatingassociations
with pattern experienced/matched, at some point it is possible that an association is
createdthatdisempowerstheindividual.
Jung,throughaprocessoftrialanderror,identifiesifanywordsareassociatedtoan
experiencethatisdisempowering.
The MIM model allows for arbitrary and automatic associations to be formed, so
should an experience produce a constant focus on this experience, the entity may not
functionwellinthefuture.
P LATO
The ancient Greeks developed many of the more enlightening aspects of human
development. Philosophy, the science Socrates believed should provide rulers for the
world,developedstronglyaroundtheyear400B.C.
Plato, Socrates’ star pupil, described the world as being comprised of objects—with
thehumanrepresentationofapureform.Formsencapsulatethepureformofanentity—
thedogginessofadog,thetreenessofanoaktree,thefemininelookofahumanfemale.
WhatdoesthismeanintermsofMIMs?
MIMs capture patterns in the environment as presented to the sensory apparatus.
Providedthesensoryapparatusprovidestherighttypeofpatternsforfurtheranalysisin
real time, the manipulation of objects automatically defines Forms—not the way Plato
suggested, as he put the chicken before the egg, but in a way that allows for the same
observationandconclusionasPlato.NotethatPlato’sFormsarenottoodissimilartothe
archetypesdetailedbymanyotherphilosophers.
MIMs capture all the patterns it experiences. That is, it captures patterns that are
presented. Whether it reduces the information into component parts, or keeps the entire
detailforlateruseisunimportant,asaMIMoperatesasablack-box.
Forexample,aMIMwillcontaineitheraverylargenumberofimagesofaspecific
object. In the case of a milk carton, it will contain the front-image, the side image, a
numberofin-betweenimages:thetopimage,thebottomimageandsoon.Thesewillall
belinkedbyassociationtothesoundofthewords“milkcarton”.Thefeel/weightofthe
cartonwillalsobelinked.Andthetemperature/coldnessofthecartonwillbelinked.And
many other linkages will exist. The fact that some information is redundant is
unimportant.Whatisimportanthowever,isthefactthatassociationlinksalargenumber
ofdifferentviewsofthesameobject.
How does a single entity comprising many views connect with Plato’s Forms? As
therearelinkagestomanyviewsoftheoneobject,thereareequallylinkagestotheviews
ofsimilarobjects.Insomeways,theshapeofthemilkcartonissimilartotheshapeofa
loafofbread,andtoacartonofbiscuits,andmanyothers.Theselinkagesareallcreated
automaticallyastheknowledgebaseisbuiltupthroughsimplyassociations.
Assumingthatthesystemautomaticallydetectsbasicpatternsinthelargevolumeof
materialstored,andthensimplifiesthenumberofassociationstothecommonlyoccurring
patterns, then the system will comprise a collection of basic forms comprising objects.
These basic forms will be the patterns comprising, say, a dog. All dogs have similar
characteristics,andalthoughsomedonotcomplywithallofthem,thereisneverthelessa
coregroupofcharacteristicsthatPlatowouldwellcallForms.
ThefactthatFormscanexistonlybytheMIM(orthehumanbrain)simplifyingthe
patterns is irrelevant. The point is that MIMs can/will automatically produce simplified
modelsthatresultintheproductionofobjectswhichareidenticaltoPlato’sconceptofa
Form.
P AVLOV ’ S D OG
The Russian scientist, Ivan Pavlov, is famous for his experiments in classical
conditioning.Henotedthatbyringingabellatthesametimeashefedadog,acurious
event would happen. A dog naturally salivates when shown food—this requires no
conditioningandiscalledanunconditionedresponse.Itisinnate.Afterconditioningthe
dogforawhile,thatisringingthebellwhileadogisshownandgivenfood,hefoundthat
ringingabellwithoutgivingfoodstillresultedinthedogsalivatingasiffoodweredue.
Thiswascalledaconditionedresponse—thesalivationbecamelinkedtotheeventthat
happened at the same time. The brain of a dog—and other animals such as humans—
appearstoautomaticallylinktogetherevents.Inthiscasethedoglinkstogetherthepattern
of ‘bell ringing’, ‘food bowl with food in it’ and ‘eat food-goody’ automatically as the
eventshappen.Theeventsmusthappensimultaneouslyfortheeffecttotakeplace.
Later,thebellbyitselfislinkedsufficientlytotriggerinthedog‘eatfood-goody’as
theanticipatedoutcome.Thisisnotintelligence—merelyanautomaticresponseofMIM
patternmatching.
Humans and dogs share a common ancestor, and our brains have remarkable
similaritiesinmanyareas.Itisworthexploringthedetailedanalysisofthiseventinterms
oftheMIMmodelpresentedhere,sincethesimilaritiesbetweendogsandhumansallows
ageneralisationtobemade.
The dog has a “memory” that connects the sight and smell of food to the digestive
process. The patterns that represent food: thousands of images, smells, tastes, feelings,
sounds, textures and so on all are linked with the response—salivation and the dog’s
body’spreparationtoeat.
Asabellissoundedatthesametimethatthedogidentifiesthefoodsource,thebrain
links these two objects together. That is the basis for the MIM model. Over repetitive
trials, the link becomes stronger—an event that has been shown to be a function of the
connectionsbetweenneuronswhenlearningtakesplace.Thestrengthoftheconnectionis
akeyelement.
Astimegoeson,thebellbecomeslinkedtoonething—thefood.Asthereisnoother
exampletodefinethebell,thesoundofthebellisanintegralpartoftheeatingexperience.
Whatthismeansisthateitherthebellorthesightofthefoodislinkedtothesameobject
—theonethatcausestheDog’sbodytopreparetoeat!
B.F.SKINNER
Skinner upgraded the complexity of the Pavlov stimulus-response conditioning. He
introduced the concept of operant conditioning (effective conditioning). Operant
conditioning,forexample,takesabirdandtrainsittodotricks,likespinningaroundto
theleftuponseeingalight.
Thebirdisfirsttrainedthatwhenitseesalight,itwillreceivefoodataspecialfeed
bin. Next, the bird is set on a table. When the bird turns to the left a bit, the light is
immediately turned on and the bird takes the food. Over a period of time, the bird
becomesconditionedtoturnaround360%totheleftwhenitseesthelight.
Skinnersaidthatthisindicatesthatthestudyofbehaviourismisontherightpath.I
suggest that this indicates, in terms of the machine intelligence model as follows: the
initialtrainingusesthePavlovmethodtotrainthebirdtolinkthelighttofood.Next,the
bird’sbraindetectsthatwhenitmovestotheleftitwillgetalightandthusfoodandthus
pleasure.Thenewpatterndetectedisthatafullturntotheleftof360degreesislinkedto
thefood/light.
Notverycomplex…
D AVID H UME
David Hume is recognised as one of the final figures in the philosophical field of
empiricism. Hume claimed that there is no “I” as the human “I” is a complex idea that
changeswithtime.Intheassumptionsofthispaper,itwasidentifiedthatthereisnobasis
forthisconceptanditwouldremainoutsidetherealmsofthemachineintelligencedesign.
As it is possible to design a machine that behaves as if it is coming from a single
source of intelligence, there is no need to actually design the machine to have a central
pointofcontrol.Thereisno“I”neededinamachineintelligence.
Further David Hume identified that the brain has a psychological property of
generalising observations to causal reality. However, simply because the brain believes
thatobservationsleadtoabeliefincausality,doesnotmeanthatthereisanactualcausal
connectionbetweentheobservation.
David Hume’s observation, that identifies science as effectively a description of the
world,isquitecorrect.Followingthatlineofthought,toproduceamachineintelligence
requirestheconstructionoftransducerstoconvertfromtheworldtosensoryinputstothe
machine,MIMstoidentifypatternsintheenvironmentandtoassociateeventsthathappen
at about the same time. This process will produce, among other things, a grammar for
languageandawaytounderstandtheworld.
S CIENCE 85—T HE C ONFESSION
Ifweembracethetheorythatthehumanbrainworksasapattern-matchingmachine
rather than a processing machine, we can see why the current approach to creating an
intelligentmachineisnotworking.Artificialintelligencereliesheavilyontheideathatthe
brainworkslikeacomputer—aprocessingmachine—soeffortstoadvancethefieldare
relyingonanoldparadigm.
Consider some of these quotes from leaders in 1985, many of whom continue to
influence the field today. Articles from Science85 highlights the trouble caused by the
adoptionofassumptionsthatarenotcorrect.M.MitchelWaldropwritesaboutthekeyAI
researchers.
Thecentralassumptionmaybesummarisedthisway:
1. Computersaremachinesthatadd/multiplyandsubtractbinarynumbers.
2. Theneuronsinthehumanbraininsomewaysrepresentbinarynumbers.
3. Therefore,thebrainmanipulatesbinarynumbersinawaysimilartoacomputer.
4. Asthebrainmanipulatessymbolsinawaythatissimilartoacomputer,itmust
have a complex process for breaking down complex images, sounds, and
thoughtsintoaformthatenablestheslowbraintoprocesscomplexsensorydata
toenablethoughttosystematicallyunderstandtheworld.
W ALDROP I NTRODUCTION
“Doing AI research is a bit like doing problems in physics or
mathematics. First turn a set of abstract speculations into a computer
program (write down the equations); then make the program perform
(solvetheequations).”,writesMrWaldrop.
Itisquiteatruestatement—andthemostlikelyreasonthatAIhasfailedtoproducean
intelligentmachine.Theassumptionhereisthatthehumanbrain“processes”information
—inthesenseoftakinginput,manipulatingit,andproducingoutput.Whilethecomputer
certainlydoesoperatethisway,whyassumethebraindoes?Whatifthebrainrecognises
input delivered from the senses, compares that information in a statistical way to all
previousexperiences,andselectsthemost(orleast,tobemoreinteresting)likelyoption
thatdoesn’tincludeacontradiction.
Forexample,saytheinputisavisionofastripedtailmovingbehindatree,withalow
growlbeingheardthroughamicrophoneandthefeeloflightrainhittingyourhead.The
growlwillbematchedbyanumberofobjects,thisisreducedbythenumberoftimesthat
type of tail was experienced at the same time, although the rain does not reduce the
numberofoptionsatall.Adragondoesn’tmatchthetypeoftail,soitisn’tconsideredfor
furtheranalysis—atigerdoesmatchalltheinformation—henceitisselected.
This process doesn’t require processing—just matching based on previously
learned/experiencedpatterns.
R OGER S HANK ’ S D EFINITION
““It can be summed up in one word,” says Yale University’s Roger
Shank, a pioneer in natural language programming. “Process. Seeing
whatthestepsare,seeingwhattheinputsare,andprovidingalgorithms
togetfromplaceAtoplaceB.”
Curious,isn’tit?Asahumanbeing,itishardtodescribetheprocessweusetotiea
shoelace,orderamealatarestaurantordecidetotakeaspecificactionwhenpresented
withalternatives—andyetwecandothesethings.Doesourbrainhaveasetofcomplex
built-inalgorithmsthataresocomplexthatwecannotreproducethem,despitebeingable
todescribethebreakdownoftheconstituentsofmattertoatomsandtheconstructionof
theuniverseintosolarsystems,stars,galaxiesandsuper-galacticclusters.
What if we learn a series of steps by simply linking together these steps, based on
repetition?Andwhatif,byexperiencingthesepatternsagain,weareimmediatelyableto
connectalltheresultsofsuchapattern?
Considerthis,whenasmallpieceofmusicisheard,thebraincaninstantlydetectwhat
themusicis,whenitwasheard,whosangit,whattheylooklike,andsoon.Thisisn’ta
processing ability; it is a linking ability. The fact that the links are already established
enables very fast access—a great difference to the process of inference or induction.
Processingwouldrequiretheinformationtobepresentedfirst,compressedintothebraincodethatmakesourobservationsofthebrainsocomplex,andthenprocessedtoconnectit
tootherinstancesofinformationthroughthesecomplexalgorithmsthatShankspeaksof.
The fact is that the neurons in the brain are slow. That we are able to find links so
quickly,indicatesthatthebrainsimplylinkingobjectstogether(associationisoneofthe
betterformsoflearningandthisiswelldocumented).Thebrainrapidlyconnectssensory
input to the previously linked objects to provide recall. These objects can be sights,
sounds, feelings—any submodality for that matter. Human memory works better when
thereismorethanonesenseinvolvedinthememory.Theseinturnarelinkedintimeand
space to other images, sounds, and feelings to represent larger objects. In humans,
language provides a further rich structure in which to understand and manipulate the
world.
T HOMASO P OGGIO :M ATHEMATICIAN OF V ISION
“Vision can be described as ‘reverse optics,’” he says. “You start with
the two-dimensional image on the retina. And from that you have to
reconstructthe3-Dobjectthatcausedtheimage.
Really?
Doweneeda3-Dconstructioninordertounderstanda2-Dimage?Thatseemstobe
drawingalongbow,indeed!
Why does Poggio consider this the case? Perhaps it has to do with the fact that
humans can manipulate visually recognised objects. There is a sense in which an object
hasmorethan2dimensions.Doesthatmeanthatthebrainhasa3-Dvisualrepresentation
ofanobject?Notnecessarily!
Whatifthebrainstoresanumberof2-Dimagesofthesameobject—inawaysimilar
tothatofamovie.Inamovie,multiplestillframesshownat25framesperminuteappear
to give a naturally moving image to the human eye. If the brain stores a few thousand
images of an object, and can access all of these images at once to give the brain the
knowledge of what the total shape of the image is, why would a 3-D representation be
required?
The brain is good at storing objects through association. In the case of vision, an
object that has continuous images through time with changes in images could easily be
storedasmultipleimagesofthesamething.
Rememberingobjectswouldbenomoredifficultthanmatchingoneofthepatternsof
the object, and then using the other stored information about the object that has been
learnedthroughassociation.
B RUCE B UCHANAN :M AKING KNOWLEDGE USEFUL
“So one of the critical research problems in AI,” says Buchanan, “is
findingefficientmeansofbuildingnewknowledgebases.”
Howdowecreateaknowledgestore?Andhowshouldwecreateaknowledgestore?
Thesequestionscertainlyhavevitalimportanceinthesearchformachineintelligence.
Today, there are a number of methods for creating databases. On a commercial basis,
databases are created for efficiency and to minimise total storage capacity for financial
reasons.FortheconstructionofAIsystems,databasesareusedthatspecifywhattypeof
informationneedstoberecordedinordertocarryoutaprocedure,suchasorderingfood,
recognisingaroomormovingaroundaroom.
Intheexamplewearemostinterestedin,inthehumanbeing,theredoesn’tappearto
be a set database that dictates what we can learn or do. One day we may have a set
procedure to follow to get to work, and the next day we may do something completely
different to get to work. One day, we may think that there are no more than 2 types of
goldfish,andyetthefollowingdaywemaydiscoverthereareanadditional15.Oreven
thatsomegoldfishhavelungs,wingsandcanfly.Thebrainhasnoapparentpreconception
aboutanyobject.
Sowhatmethodmakessensetobuildnewintelligentdatabases?Howshouldwedo
it?
An obvious method is one that is self-generating based on association and pattern
matching. The associations take place automatically whenever two patterns are active at
anyonetime.
The model discussed earlier, with MIMs providing non-intelligent pattern matching
and association creation, provides the capability to produce a database without the need
forapredeterminedstructure.Anytimetwoormoreobjectsareactiveatthesametime,
theybecomeassociated.Forthisreason,dinnermayinvolveflamingkebabs,magnumsof
drink and gallons of ice cream—without the need to categorise dessert, entree, or main
course.Retrospectively,thesecategoriesbecomedefinedasicecreamisadessert.
Followingthroughtheassociationsanotherway,itbecomesapatternthattheorderof
foodsinamealisentree,mainandthendessert.
The fact that savoury foods come first, followed by sweets is another pattern that
emergesfromtheassociationsbetweendifferentmealsovertime.
G EOFFREY H INTON :P ARALLEL INTELLIGENCE
“Untilweknowhowtodotheproperprogramming,”saysHinton,“we
wouldn’tknowwhatkindofparallelsystemtobuild.”
The chicken and egg story is one that has baffled scientists for eons. The MIM
structure is one that benefits from its parallel design. The fact that memory and
associations are based on predetermined patterns, and that knowledge is one in which
largenumbersofassociationsareconsideredsimultaneously,demonstratesthatthetypeof
parallelsystemtodesignisoneinwhichmemorycanbesearchedsimultaneously.
Geoffreyisfocussedonprogramming,whichisaverydifferentparadigm.Towritea
program to learn is a difficult thing, indeed. To write a program to match patterns and
connect/createassociationswhentwoormoreeventshappensimultaneouslyisadifferent
matter.
Thefactthatitisdifficulttowriteagenericprogramtolearn,builddatastructuresthat
require dynamic change, and provide the ability to reconstruct the data elements
retrospectively,isadifficulttasktoperformwithCOBOL,C++orLISP.
T ERRY W INOGRAD :E NGLISH AS A COMPUTER LANGUAGE
“Theideaisthatlanguageandthoughtcanbemodelledbysuchthings
as formal logic,” he says. “But I think that is grossly oversimplified.”
Winograd feels that a great deal of what goes on when people talk
happensatadeep,perhapsunconsciouslevelwedon’tyetcomprehend.
“Whatpeopleactuallydohasverylittleincommonwithformallogic,”
hesays.“Andwhat’smissingisthesocialdimension.Onceyoutakeinto
accountwhatyouareusingawordfor,whatpartitplaysindiscourse,
thereisnoboundarytothemeaningofthatword.”
Winogradhighlightsthefactthatlanguagehaslittletodowithformallogic.
In fact, language builds up automatically as children experience the world. The
process of linking the sound of words to objects creates meaning to those words. The
orderofwordscreatesgrammar.Thelinkagebetweenthemeaningsofthewordscreates
storieswhichprovidepatternsofmeaning.Thesepatternsofmeaningrepresentcontext.
Languageistheassociationofwords,linkedtotheirmeaningsandwiththemeanings
linked to create understanding. A vast network of intertwined words, images, sounds,
feelingsandothersubmodalities.
H UBERT D REYFUS :
T HE B LACK N IGHT OF AI
He maintains that computers will never be able to think because
scientists will never come up with a suitably rigorous set of rules to
describehowwethink.
Dreyfus makes the case for intuition. He argues that perception,
understanding and learning are not just a matter of following discrete
rules to compute a result; they’re holistic processes that make possible
our status as human beings living and breathing and interacting in the
world. This view is supported by recent psychological studies in
categorisation.Wheredowedrawthelinebetweenavaseandacup?It
depends on the context. How do we know that an A in Old English
typefaceisthesameasanAinTimesRomantypeface?Certainlynotby
counting serifs. If these really are intuitive processes, then Dreyfus is
right:Thequestforlogicalrulesisasenselessone.
The argument of Dreyfus is that “intuition” is more than discrete rules. He has
providedaworthyobservation.Itistruethattheideaofarigoroussetofrulestodescribe
howwethink,maybesimilartotryingtofindarigoroussetofepicyclesthatexplainthe
motionoftheplanets.However,itisnotclearwhatitmeanstothink—forthatreasonthe
assumptionisthatthereisnosuchthing.
Itistruethatignoringtheissueofthinkingmakestheideaofsettinguprulestothink
alsoirrelevant.Consideringthefactthatintuitionisdefinedasthe:“directperceptionof
truths,facts,etc.,independentlyofanyreasoningprocess.”Thatisanimportantstatement.
Ifthereisnosuchthingasareasoningprocess,allactivitywhichpeoplemayclassifyas
thought,becomesintuitivethinking.
The model explained above, in which MIMs detect patterns in the sensory
information presented, becomes a machine in which its processes are based around
complexinterconnectionsofobjects.Whenlookingfortheworst,butcomplete,fittoaset
ofconditionstheMIMmodelenablestheselectionofasolutiontoaproblem,withoutthe
needforcomputationorreasoning.Rather,theMIMmodelproducesoutcomesbasedonly
onexperience,notonacomputationalbasisoramethodbasedonreasoning.Reasoningis
ratheraprocessthatcanbeestablishedthroughtheMIMmodelasanexplanationafterthe
eventfordecisionsthatneedtobejustified.
Some of the experiments that have been performed on commissurotomy patients
(thoseinwhichtheircorpuscollasumhasbeensevered)indicatethatifapartofthebrain
compels a motion, the language part of the brain will explain it. This is despite the fact
that the language part of the brain had no access to the part of the brain that made the
decisiontomove.Itcouldbesaidthatthebraincanexplaineventsithasnoknowledgeof,
but explain the observed events in terms that are not inconsistent with all observable
information.
The MIM model is one which produces a holistic result. The system uses all the
availableconnectedinformationinordertoproduceanumberofpossibleresults—thenit
isaquestionofwhichonetochoose.Furtherinformationmustbeaddedtothesystemin
ordertoproducearesultwhenprovidedwithinsufficientinformation.
Let’sconsidertheissueofcategorisation:whatisthedifferencebetweenavaseanda
cup?Thevisualimagemaynotidentifyit—northesubmodalitiesofcolour,texture,size,
temperature.Itdependsonotherfactors.
Where do these other factors exist that enable us as human beings to make the
distinction which we normally can make? When we are taught the word “vase”, we are
probably seeing an image of a cup with flowers in it. Over time, a number of vases are
seenandaddedtoourmemoryforfutureuse.Similarly,anumberofcupsarestoredwith
informationabouthowtheylook,feel,smell,whatsizetheyare,whatcolourtheyare,and
soon.
Aswegrowolder,wehavemoreoftheseimagesstoredinourbrain—withthesound,
spelling,andfeelingsabouttheobjectsstoredthroughassociationaslinkedobjects.
Sowhentheneedtodifferentiatebetweenavaseandacupismade,thebrainisable
to use the network of connections for vase to compare the information presented. A
comparisonwiththenetworkofobjectsforthecupwillenableadecisiontobereached
basedonprobability.Ifthecupisshownwithflowersinit,thevasewillcertainlywin.If
the vase is shown with cappuccino in it, the cup will win. It comes down to the
associationswhichmeansitcomesdowntowhatisbeingcalled,context.
InthecaseoftheoldeEnglishAversusthemodernA,itmakessensethatthebrain
doesn’thaveaprocesstocounttheserifs.However,thereisalotofinformationavailable
aboutthelookofthepagethatindicatesthattheobjectsbeingconsideredareletters.There
willbemanyassociationsthatwillhelptoconfirmthis.
Someoftheassociationswillbethelookofthebook—thousandsofdifferentbooks
will be linked together in the visual MIM area to identify the book. Similarly, the olde
English A will be matched most closely by the saved patterns for A’s previously seen.
TheremaybeathousanddifferentAsstoredinatypicaladulthumansbrain.Thismeans
thatrecognitionisn’tamathematicaloracomputationalchallenge,ratheritisapatternmatchingproblem.
Wecanknowthattwoletterareidenticalbecausewehaveexperiencedthefactbefore
—therewouldbenowayforarandomlyconstructedalphabetortypefacetobeidentified
priortopreviousidentificationorinstruction.Havingsaidthat,onastatisticalbasis,which
isthebest-fitoutcomefortheMIMcomponent,thebrainisabletoidentifyanAthathas
neverbeenseenbefore,providedthatitlooksmostlikeanotherApreviouslystored!The
bestfitapproachisusedfrequently,whichishowwecannavigatethroughforestswithout
gettingconfusedbythenumberoftreesweseethatdifferfromeveryotheronewehave
experienced.
T HE R OOTS OF M ORALITY
Piaget postulated that younger children are self-centred and do not yet
havethecognitiveskillstounderstandthepurposeofsociety’srulesnor
theabilitytousetheminareasonedapproach.
Butaroundtheageof10,children’scognitiveskillsreachthepointwhere
they can interpret society’s rules and become aware of the effects of
violating them. They also begin to use their emerging intellectual
capabilitiestoreachhigherlevelmoraljudgements,whichincludemotive
andintent.
HowcanweusethistofurtherexplaintheMIMmodel?Piagetobservedadifference
in behaviour between children of different ages. In the MIM model, there are levels of
pattern matching. Prior to having patterns for the constituents for sounds the level of
MIMsthatdetectpatternsinthatlevelcanhardlygenerateanyusefulpatterns.
Similarly, in children, it makes sense that as the brain develops more complexity
through increased numbers of patterns and associations, that higher level of pattern can
subsequentlytakeplace.Itmaywellbethatatageten,therearesufficientexperiencesthat
enable the detection of pattern related to society’s rules that were not available prior to
that.
Toprovethiswouldrequireanexperimentinwhichcertaincontrolchildrenwerenot
allowed to experience situations in which society’s rules were not made available and
compare the children after a year or two. That kind of research becomes entwined in
ethicalissues.
I MPLICATIONS OF MIMT HEORY
The MIM theory described above radically changes the view of the human brain,
intelligenceandourviewonthecomplexityoflife.Whatanamazingconcepttoconsider!
And the next 20 years will see vast changes in machine performance as these ideas are
convertedintousefultoolstohelphumans.
H ERIDARY V ALUE
The machine intelligence discussed here will have some properties that may prove
similar to biological life forms. If the MI is able to link a number of high-level actions,
such as imitating another being, to pleasure—then it will be able to condition itself to
pursue activities that are pleasurable. Equally, if actions lead to pain, the MI will avoid
thoseactions.
On a commercial aside, the process of language understanding requires the
construction/generation of a complex of interconnected memory elements—once this
structurehasbeenlearnedonce,itmayformthebasisofmanyidenticalunitstofollow.In
the same way that cloning copies the raw biological material blueprint, but not the
memories of the individual, copying the basic framework for machine intelligence, the
languagecentres,doesn’tmeanthatallmachineintelligenceswillbethesame.Therestis
experience!
C ONCLUSION
Therearetwomajorissuesinthecognitivesciencesthatarestilloutstanding.Oneis
themanipulationoflanguage,theotheristhemanipulationofourvisualworld.Both
currentlyhavecomputationaltheoriesconnectedwiththem.Bothhavethecapabilitytobe
handledbyasingletheoryofstoragemanagement.Bothcanutiliseaparallelhardware
technologythatissimpleandconstructible.
Ourlimitationsintheprogressofintelligentsystemsarereallyoneoftheconstruction
ofhardwareandsoftwaretosupportthenewconcepts.Thesenewsystemsrequire
developmentwork,clearly,andarenofurtheralongtheevolutionarylinethanthe1950
ENIACtothecurrentDigitalpersonalcomputer.
Thebenefitsandimplicationstohumanityarevast–therewillbeimplicationsto
psychology,thecognitivesciences,medicineandthetreatmentofthementallyand
physicallydisabled.
Therehasbeenmorethan2500yearsofphilosophicalprogressformnatural
philosophyinGreeceinthetimearound400BCtothepresenttime.Historyhasenabled
theconstantbuildingofideasusingthefuzzyandmisleadingconceptssuchasideas,
thinking,consciousnessandmind.Itistimetomoveonwiththedevelopmentofsystems
thatassisthumans—systemsbasedonmachineintelligence.Galileoupsetthetraditional
thoughtofhumanity’spositioninthecosmos.Darwin,followedbyFreudcontinuedthe
trendtothepointwherethecommonpersonistodayawareofthedifficultyfacingour
modernhumanfamily.
ThewayforwardistobuildmachinesusingthenewlinkedsensorymodelthatMIMs
holdtogether.Throughthisexplorationandexperimentation,ourappreciationofthe
marvelofhumanitywillcontinueforthecenturiesthatfollowaswefocusonthe
challengesofthenewage.
A PPENDIX A.A DDITION AND M ULTIPLICATION WITHOUT
PROCESSING
Theideaofmultiplyingandaddingnumberswithouttheneedforcomputationisalien
tothestandardtreatmentofintelligence:isn’titprocessingthatdeterminesintelligence?
Afterall,acalculatorprocessesnumbersusingacomputationaldesign,whynotan
intelligentmachine?
Rememberthatthespeedofprocessinginahumanbrainisroughlyamilliontimes
slowerthaninatypicalcomputer—atleastintermsofsignaltransmissionandinthe
numberofcomputationsacomputercanperforminasinglecycle.
Ifthebrain’sspeedisduetoadifferentmechanism,thatcanexplainhowahumancan
performlightning-fastcalculations,oncesuitablytrained.Itisinterestingthatfewpeople
possessthecapabilitytoaddlargestringsofnumberssuchas3+4+123+67+12+122+…
althoughmanycanadd4+6,forexample.Coulditbethatthebrainisusingasystem
basedonmemory,inasimilarwaytothatproposedintheMIMmodel?
Let’sloadanMIMwithsomepatterns—startwiththefollowing:
1+1=2,1+2=3,1+3=4,1+4=5,1+5=6,etc.
Nowlet’squerytheMIM:whatistheanswerto:“1+3=”?
TheMIMwillrespond(inonememorysearchperiod)with“4”.Noprocessingis
required.Itissimplyapatternmatchingexercise.Processingisaniceideaforsolving
mathematicalproblemsusingthetechnologyavailableinthe1950s—itmakesnosense
today!
TheMIMdesignmaybeusingbrute-forcesearchingandstoragealgorithms,or
elegantneuralnetworkstoragemechanismsbasedonhistoricalprobabilities.Thebeauty
oftheMIMapproachisthatbydesigningtheMIMasablack-boxproducingaspecific
result,themechanismisunimportant.
A PPENDIX B.A SSUMPTIONS
Thispapermakesuseofthefollowingassumptionsaboutthehumanmindinorderto
understandhowtoproduceanintelligentmachine:
1. Thehumanbrainandnervoussystemisaphysicalmachinethatcanbecopiedas
thebasisformachineintelligence.
2. Thereisnomind.Thethingcalledthehumanmindmaybeacollectionofmachines
operatingindependently.Assumingthatamindexistsprejudicesourmodeltowardan
entitycontrolledbyacentralthing.
3. Thereisnoconsciousness.Althoughthemachinemustbeawareofitsenvironment
andhavethecapabilityoffocussedattentiontoasubsetoftheexternalworld,thereis
no single entity that is the single controlling feature. The term consciousness again
suggestsasinglecontrollingentitythatmaybesimplyaby-productofourlanguage
use—humans think they are a single entity based on their language which uses
singulartermsforthe“self”(suchas:I,me,myself,mysubconsciousmind).Thefact
thattheinternalquestion:“WhatamI?”presupposesthat“I”isasingleitem—thiscan
bemisleading.
4. Thereisnosubconsciousorunconsciousmind.Freud,Jungandmanypsychologists
usethemodelthatstatesthatthereisapartofourmindwhichholdsinformationnot
availabletoourconsciousmind.Theterm‘unconscious’suggeststhatthereisasingle
entity that is in our brain that enables or forces us to behave as we do. This
information is often used in our law courts to explain why individuals are not
responsiblefortheiractions.Afterall,wearenotresponsibleforthat“otherself”,the
subconscious.Whatifthesubconsciousistemporarilybroken?Themachinewebuild
will not act on all stored information at the same time—some available information
maybeusedtomakeadecision,althoughitwillnotbespecifiedintheanswer.This
does not mean that the machine has a subconscious mind, only that its actions are
based on information not made public. There is more information stored than is
communicated.
5. Dreamsdonothavemeaning.Theintelligentmachinewillreduceitsstorageusage
bycombiningpiecesofinformationinitsdatabaseofknowledgethroughaprocessof
consolidation.Thisprocessrequiresthesystemtobeshutdowntonewinformationin
ordertoavoidinterferingwiththenormaloperationofthememorysystem.Shouldthe
system be observed during this time of consolidation, it may appear that there are
images,feelings,andothersensesactivethatnormallyhasmeaning.Meaningcanbe
foundinalmostanythingthatisprovidedtothemachine.Thisisduetothedesignof
themachine(thecombinationofinformationusingtheprocessofassociation).Aheart
and a box of chocolates has meaning to most of us, and a dream about these two
objectshasnomeaningotherthanthesystemispossiblyreducingtheredundancyof
theassociationsbetweenheartsandchocolates.
6. Psychoanalysis is a method of understanding learning, not to understand the
unconscious.Humanpsychoanalysisaimstoexplaintheunconscious.Intermsofan
intelligent machine, psychoanalytic procedures such as free association enable the
tracing of patterns of association that makes up intelligence. These patterns are the
cornerstone of the new intelligent machine and represent valuable pieces of
knowledge about why the machine does what it does. Remember that there is no
intelligence about what is stored. It is simply a process of pattern matching and
linkagethroughassociation.Ifassociationstoresincorrectinformation,thereneedsto
beamechanismtocorrectit.
7. Humanthoughtisanoutcomeproducedbythebrain—itisnotasingleprocess.
The process of thinking is a term for labelling the passing of time during which the
brain produces an outcome. The outcome is usually based on some of the initial
conditions of a situation. Thought is definitely not: (a) a centralised function
controlled by a “self”, or by (b) the subconscious, or by (c) any other term
representingadescriptionofanobjectnotdemonstratedtoexist.
8. Thoughtisnotacomputationalprocess.Thereisnoreasontoassumethatthought
exists as a computational process. Thinking appears to combine information that
requires inferences and deductions to be made. This process may be the result of
memory storage and recall not based on processing at all. The example of parallel
additionshownlaterdemonstratesthis(seetheexampletoadd“1+4”inAppendix
A).
9. Computermemorydoesnotworklikehumanmemory.Computermemoryisreally
simply a store (a place to store information)—memory (and in particular human
memory)isandmustbeanactivecomponent.
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