1 / 20

Clark Leonard Hull (1884-1952)

Clark Leonard Hull (1884-1952). A Cognitive Behavior Theory (and yes, we are skipping over Skinner! Leaving the best for last!). Clark Hull. U of Wisconsin grad: PhD in 1918; most of career at Yale Three separate parts of career: Testing of aptitudes: Aptitude Testing (1928)

pilar
Download Presentation

Clark Leonard Hull (1884-1952)

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. Clark Leonard Hull (1884-1952) A Cognitive Behavior Theory (and yes, we are skipping over Skinner! Leaving the best for last!)

  2. Clark Hull • U of Wisconsin grad: PhD in 1918; most of career at Yale • Three separate parts of career: • Testing of aptitudes: Aptitude Testing (1928) • Hypnosis: Hypnosis and Suggestibility (1933) • Study of learning processes: Principles of Behavior (1943) • Most important of work • Revolutionized study of learning with methodology and modeling • 40% of all experiments in JEP and J of Comparative/physio psych from 1941 to 1950 referenced his theory • Most often sited experimental psychologist until mid 1950s • Interesting fact: had childhood polio and was quite disabled much of adult life

  3. Hull’s approach to theorizing • Major influences: • Darwin and concept of adaptive behavior • How do organisms adapt to environment and what factors are involved • Used Hypothetical Deductive or logical deductive approach: • Develops a set of postulates or principles • Deduce from these a set of inferences or theorems using strict logic • Theorems/postulates often involve hypothetical constructs invented by theorists to describe relationships between experimental manipulations and the data • Evaluate the theory by translating deductions from theory into experimental operations and see if data support

  4. Hypothetical deductive? • Why use hypothetical deductive approach? • Creates dynamic, open ended system • Constantly generating hypotheses • Constantly evaluating hypotheses with experiments • If data support: strengthens theory • If data not support: revise the theory • Remember: theory merely a tool that aids researcher in synthesizing facts/organizing methods of looking at data • Ultimate test = your data!

  5. Major Theoretical Concepts • Based on logically structured set of postulates and theorems • Based on Euclid's geometry • Postulates = general statements about behavior that cannot be directly verified • Theorems that logically flow from postulates CAN be tested

  6. The 16 postulates (yes, 16!) • Postulate I: Sensing the External Environment and Stimulus Trace • External stimulation triggers an afferent neural impulse • This impulse outlasts the environmental stimulation • This “left over” neural impulse = stimulus trade (s) • It is this neural impulse that becomes associated with environmental event • Also: neural motor reaction (r) that results in overt response (R) • Thus: S-R becomes S-s-r-R • (Actually is now evidence neurologically to support this!)

  7. The 16 postulates • Postulate 2: Interaction of Sensory Impulses • Interaction of sensory impulses ( s ) indicates complexity of stimulation • This complexity demonstrates the difficult of predicting behavior • Behavior rarely function of only 1 stimulus (novel idea at that point) • Important concept: stimuli interact with one another • Related traces interact with one another • Synthesis of these interactions determines behavior • Can draw this function: S1s1 S1s1 S1s1 srR S1s1 S1s1

  8. The 16 postulates • Postulate 3: Unlearned behavior • Organism has an innate hierarchy of responses: • Unlearned behavior • Triggered when a need arises • Needs = physiological • Hunger, thirst, aggression, temperature control • Motivated behavior • Hierarchy because more than one response/reaction may occur to a need • If first response does not reduce need, then second response elicited, and so on • If innate responses do not resolve need, this creates need for learning • Learning only required when innate responses do not resolve a need

  9. The 16 postulates • Postulate 4: Contiguity and Drive Reduction as necessary condition for learning • If S leads to R, and IF R results in satisfaction of biological need, the association between S and R is strengthened • More often the S-R association occurs, the stronger the relation and the stronger the R is to the S (Basically restates Thorndike’s law of exercise) • Primary Reinforcement MUST involve need satisfaction or drive reduction

  10. The 16 postulates • Postulate 4 also addresses secondary reinforcers: • Reinforcer = S that has been closely and consistently associated with diminution of a need” • Secondary reinforcer following a response also increases with S2-R pairings • If a S is followed by an R, which in turn is followed by a reinforcer, the association between the S and R is strengthened • Habit strength: SHR • Note that is very specific: a reinforcer MUST reduce a drive • One of most important concepts: refers to strength of association between S and R • Can mathematically model: • SHR =1-10-0.0305N • N= # of pairings between S and R • Formulates negatively accelerated learning curve

  11. The 16 postulates • Postulate 5: Stimulus Generalization • Ability of new S’s to elicit conditioned R is determined by similarity to the original S+ used during training • SHR will generalize from 1 S to another to extent that 2 S’s are similar • Prior experience also matters: • Learning that takes place under similar conditions will transfer to new learning situation • Generalized Habit Strength: SHR • Identical to Thorndike here

  12. The 16 postulates • Postulate 6: Stimuli associated with Drives • Biological deficiency in organism produces a drive (D) • Each drive associated with specific stimuli • E.g., hunger = stomach growling; thirst = dry lips, etc. • Existence of specific drive S makes it possible to teach animals to behave differently for different drive states • Can respond one way to hunger stimuli; another to thirst stimuli • Drive states can be elicited by different stimuli

  13. The 16 postulates • Postulate 7: Reaction potential as function of Drive and Habit Strength • Likelihood of learned response emitted at any point in time = reaction potential or SER • SER = f(SHR x D) • SHR must be activated by D • Drive does not direct behavior, just arouses it • D is motivator: arouses and intensifies R • Without D, animal cannot engage in learned response even with strong association • Must be a motivator, so to speak • Is a motivator in that engages behavior • Thus: reaction potential = SER = f(SHR x D) • If SER or SHR = 0, then reaction potential must be 0 • Reaction potential also related to resistance to extinction, latency and amplitude of response

  14. The 16 postulates • Postulate8: Responding causes Fatigue, which operates against the elicitation of a conditioned response • Responding requires work; work results in fatigue • Fatigue eventually inhibits responding • Reactive inhibition (IR): • Caused by fatigue associated with muscular activity • Related to amount of work involved in response • Automatically dissipates when organism stops performing • Used to explain spontaneous recovery: • no longer fatigued! • After rest, IR dissipates, animal begins to respond again • Extinction also influenced by IR

  15. The 16 postulates • Reminiscence effect: • Improvement of performance after a break • Explained by assuming that IR builds up during training; operates against tracking performance • After rest, IR dissipates, performance improves • Evidence? • Data from massed vs. distributive practice • Distributive practice = better performance/learning • Modern theorists disagree with “how” but reminiscence effect is strong and needs to be dealt with…..

  16. The 16 postulates • Postulate 9: Learned response of NOT responding • Fatigue = negative drive state • Thus: not responding = reinforcing • Allows IR to dissipate • SIR = conditioned inhibition: • Learn not to respond (reinforcer is decrease in fatigue) • Note that IR and SIR work against each other • Subtracted from reaction potential: Effective reaction potential • Thus: effective reaction potential = SER=SHR X D – (IR + SIR)

  17. The 16 postulates • Postulate 10: factors tending to inhibit a learned response change from moment to moment • Inhibitory potential = oscillation effect: SOR • Varies from moment to moment within limited range • Values are normally distributed: • middle values most likely to occur • Explains why learned behavior may not occur in given instance • Operates against elicitation of learned response • His fudge factor • Can now quantify: Momentary Effective Reaction Potential = . SER=[SHR X D – (IR + SIR)]- SOR

  18. The 16 postulates • Postulate 11: momentary effective reaction must exceed a certain value before a learned response can occur . • Reaction threshold = SLR = the value that SER must exceed for conditioned R to occur . • Learned response will only occur if SER > SLR • Postulate 12: probability that a learned response will be made is combined function of . SER, SOR and SLR • After a few reinforced trials, SER approaches SLR • because effects of SOR on conditioned response elicited on some trials, but not others • On some trials: value of SER-SOR is large enough to reduce SER to value below SLR • As training continues, subtracting SOR from SER has less and less effect (value of SER becomes much larger than value of SLR) • BUT: even after long training, possible for SOR to assume large value, thus preventing conditioned response

  19. The 16 postulates . • Postulate 13: The greater the value of SER, the shorter the latency between S and R • Latency(STR) = time between presentation of S to organism and its learned response • Reaction time between onset of S and elicitation of learned R decreases as value of : SER increase . • Postulate 14: The value of SER will determine resistance to extinction . • Value of SER at end of training determines resistance to EXT • EXT = how many non-reinforced responses made before extinction occurs . • The greater the value of SER, the greater the # of non-reinforced trials that must occur before EXT • n = number of non-reinforced trials that occur before EXT . • Postulate 15: Amplitude of conditioned response varies directly with SER • Some learned responses occur in degrees • When conditioned response is one that can occur in degrees, its magnitude will be directly related to size of SER = momentary effective reaction potential • Postulate 16: when 2 or more incompatible responses tend to be elicited in the . same situation, the one with the greater SER will occur.

  20. Summary of Terms • D = drive • SHR = habit strength • SER = reaction potential = SHR X D • IR = reactive inhibition • SIR = conditioned inhibition • SER = effective reaction potential = SHR x D-(IR+SIR) • SOR = oscillation effect . • SER = momentary effective reaction potential = SER-SOR= [SHR X D - (IR+SIR)]-SOR • SLR = value that SER must exceed before a learned response can occur • StR = reaction time • p = response probability • n = trials to extinction • A = response amplitude

More Related