A theory of associative learning

Question 1

how did we learn about causality using associative learning?

Answer 1

• All species live in a world in which they need to predict and control the world around them to survive
• Associative learning found across animal kingdom – all vertebrates and invertebrates, and even in monocellular organisms such as planaria – and maybe plants?!

Question 2

what is delay conditioning?

Answer 2

an unconditioned stimulus (for example, an electric shock) is introduced in the final moments of a conditioned stimulus (for example, a tone), with both ending at the same time

Question 3

what is trace conditioning?

Answer 3

a form of associative learning that can be induced by presenting a conditioned stimulus (CS) and an unconditioned stimulus (US) following each other, but separated by a temporal gap

Question 4

what is simultaneous conditioning?

Answer 4

when the conditioned stimulus and the unconditioned stimulus are presented at the same time

Question 5

what is backward conditioning?

Answer 5

occurs when a conditioned stimulus immediately follows an unconditioned stimulus

Question 6

Evidence for backwards conditioning, Mahoney and Ayres (1876)

Answer 6

• study on rats
• 4 second tone was paired with 4 second shock in variety of ways: delay conditioning, trace conditioning, simultaneous conditioning and backward conditioning
• Rats didn’t learn much if tone after shock
• learned more if tone simultaneous with shock
• learned most if tone before shock
• CR is suppression of licking. Measure is lick latency, how long it takes them to start.
• high latency = high fear

Question 7

Importance of correlation in associative learning, Rescorla (1968)

Answer 7

• three groups of rats given 5 tones and some shocks
• group 1: positive - 2 tone = shock pairings, no more shocks
• Group 2: zero - 2 tone = shock pairings, plus extra shock
• Group 3: negative - shock never paired with tone
• group 1 showed the tone was positively correlated with shock
• group 2 showed the tone was uncorrelated with shock
• group 3 showed the tone was negatively correlated with shock
  since pPositive and zero groups got the same number of tone →shock pairings but they did not learn the same
• shows pairings are not everything and correlation is important

Question 7

Kamin (1969)

Answer 7

• In Group 1 light conditioned with a pretrained noise N
• In Group 2 light conditioned with a novel noise N
• In Group 1 shock not surprising – predicted by pretrained noise
• In Group 2 shock not predicted, and is surprising
• found Less learning in Group 1, where shock not surprising
• The pretrained noise blocked learning about the light in Group 1
• This crucial observation, that pairings only produce learning when the US is surprising, is captured by Rescorla & Wagner theory

Question 8

what does the Rescorla and Wagner (1972) theory describe?

Answer 8

describes how much association strength increases on each trial (i.e. CS→US pairing)

Question 9

Rescorla and Wagner (1972) theory equation

Answer 9

∆V = αß ( λ - ∑V )

V is associative strength between CS & US

∆V is change in V after each pairing

α refers to salience of CS - its intrinsic perceptual intensity

ß refers to salience of US - its intrinsic perceptual intensity

λ refers to size of US - another physical property

Question 10

what is α

Answer 10

salience of CS

Question 10

what is ß

Answer 10

saliency of US

Question 11

what is λ

Answer 11

the size of the US

Question 12

Conditioning two CSs at once: Overshadowing, Mackintosh, (1976)

Answer 12

• Equal numbers of pairings of light with shock, but in overshadowing groups a noise also present – either quiet n or loud N
• most learning in control and with quiet n less learning with loud N
• When two stimuli conditioned in a compound, both help predict the US.
• On trial 1 learn about light and noise
• On trial 2 light and noise both help predict US
• Light and noise are competing for strength – if light gets more, the noise has to get less, or vice versa
• If α light= α noise they compete equally, and each gets half total strength
• But if noise more salient than light
• α noise&raquo_space; α light
• noise will get more than half strength acquired on each trial
• In control group light gets all
  the associative strength
• In overshadowing group strength
  is divided between light and noise
• In blocking group noise gets all
  strength in stage 1, so none
  left for light!

Question 12

what is ∑V?

Answer 12

• how much of the US is predicted
• the sum S of the associative strengths Vs of everything else that is present on that trial

therefore ( λ - ∑V ) is how surprising the US is
- if US is very large (λ big) it’s more surprising - if US is well predicted (∑V big) it’s less surprising

Question 13

Why don’t warning signals extinguish?

Answer 13

• In avoidance learning avoidance responses persist
  even though warning signals haven’t been paired with
  shock of ages
• this is because the conditioned inhibitors predicting the absence of shock
• Even though the warning signal is presented without shock, it is accompanied by the response which is inhibitory

Question 13

what is an inhibitor?

Answer 13

• its negative associative strength subtracts from other predictors of the US
• and because it starts negative it takes longer to predict the US itself