1. Social Dev. Theories Exercise
Name all psychological/behavioral gender differences you can.
Name all gender stereotypes you can.
How would each of the following types of theorists explain such gender differences:
Behaviorist learning theorists?
Social Learning theorists?
Social Cognition theorists?
Bioecological theorists (how would each of the 5 systems influence gender)?
Evolutionary theorists?

2. Gender Development

4. Gender Differences Across Dev.
Toy preferences as early as 1 year
Not only preference for gender typical toys but neutral toys if believed gender appropriate
Play Style
Rough and tumble play
Large vs small groups
Competition (50% males, 1% females)
Pretend play (heroes vs. families)
Aggression (physical vs. verbal/relational)
Communication
Shared emotion vs. shared activities/interests
Problem solving: Compromises vs. physical force

5. Gender and Learning Theories
Behaviorist Learning theories:
Reinforced: Encouragement, rewards, punishments, peer pressure
Social Learning theories:
Children learn about gender through observations: (parents, peers, media) and direct teaching
Observing their own gender more

6. reward gender appropriate behavior Buy gender appropriate toys
Direct Teaching:
PARENTS DO:
reward gender appropriate behavior
Buy gender appropriate toys
(could be result of child’s pre-established prefs)
are supportive of sex-appropriate play
Talk differently to children (e.g. emotions)
PARENTS DON’T:
Display a difference in warmth
Differ in interactions or responsiveness
Overall not more restrictive in activities
By years already differ in terms of toy pref.
Before birth differ in activity level

7. Gender and Social Cognitive Theories
Look at the development of gender-role knowledge
Kohlberg’s Cognitive Developmental Theory
Children actively construct knowledge of gender:
3 Stages of Gender Development
Gender Identity (2 years; knowing who you are)
Gender Stability (3-4 year; knowing gender is stable over time)
Gender Constancy (5-7 years; stable over time AND situations—not influenced by superficial changes)

8. Gender Schema Theory Gender self-socialization
Children develop gender schemas, which are mental representations incorporating everything they know about gender
Gender self-socialization
the child determines what other info they learn about gender
E.g. initial prefs for trucks leads them to learn more about trucks and little about dolls
Schemas lead to a confirmation bias (remember info that “fits/confirms”schema and distort or forget other info)
[think back to Dodge’s info processing, how we encode and interpret info]

9. 4. Gender and Ecological Models
Bioecological Model
Children learn and are influenced by gender at every level
e.g. room they live, occupations/genders of neighbors, media, belief systems of the culture, time period etc.

10. Gender and Evolutionary Models
Evolutionary Psychology
Gender behaviors are genetically based to influence survival and mating
E.g. physical activity, aggression in males due to “hunter” characteristics, need to compete for mates
E.g. nurturance and emotional characteristics in females, playing with dolls is the ‘caregiver’ in females
Parental investment theory (differences in relationships/behavior due to different investment needs of males vs. females in passing on genes)

11. Biological Explanations
Female rats and rhesus macaques treated with testosterone = increased male-typical sexual behavior, rough and tumble play, activity level, aggression
Critical periods (different for different sex-typed behavior)
~8 weeks gestation – 6 months of age

12. Biological Explanations
CAH Congenital Adrenal Hyperplasia
a group of inherited disorders
deficiency in steroid hormones (cortisol and aldosterone) which leads to overproduction of androgen (male sex hormone)
Rare: 1 in 2-20,000 births
Females: ambiguous genitalia, “masculine” physical traits
Males: enter puberty much earlier

13. Biological Explanations
CAH girls/CAH induced (androgens in pregnancy)
More time with “male” toys
Greater preference for male playmates
Reduced gender identity/Less satisfaction with gender
when androgen reduced during pregnancy females = more feminine clothing
Mixed results on aggression/rough-&-tumble play

14. Gender: Integrating the Theories
Maccoby’s theory combines evolutionary and biological data with ideas of gender schema (cognitions) and social models
Biology leads to differences in play styles
Observation + direct teaching + Peer Pressure
Self-socialization, gender segregation by compatibility
Video on CAH and Gender Development!

15. Conceptual Development When, Where, Why, and How Many?
Concepts are general ideas or understandings that can be used to group together similar
Objects
Events
Properties etc.
Concepts help us simplify the world and think more efficiently.
e.g Boy Scout rule for being lost in the woods without food
e.g. possible origin of stereotypes?

16. Perceptual Categorization
Grouping according to similar appearances (size, color, movement..)
children first categorize according to overall shape, then later by function

17. Using Concepts to make Inferences
9-10 month olds expect similar looking objects to perform the same function (e.g. castanets study)
By age 2, children can categorize to determine which actions go with which objects (e.g. knowing if a cup is used to “feed” an animal it can be used to feed a another animal but not a vehicle.)

18. Language Concepts
Language could not be learned without concepts (how would we know how to generalize word meanings?)
Language can serve to point out NEW concepts (e.g. Xu and Carey--individuation)
Pragmatics of language can emphasize importance or add weight to concepts (e.g. “carrot-eaters” versus people who eat carrots)

19. Time: Order of events Knowing what happened first, next, and so on…
3-month-olds can detect the order of events in a repetitive sequence.
Pictures are shown alternately at A and B.
Over time, infants start to anticipate the new picture.
By 12 months, they can detect the order after only a single exposure to the sequence. A B
(Baby)
Mom
Haith, Wentworth, & Canfield, 1993; Bauer, 1995

20. Time
4-year-olds can report that an event (e.g. birthday) that occurred a week ago was more recent than an event that happened 7 weeks ago (e.g. Christmas)
If event happened more than 2 mths ago, they aren’t very accurate until age 9
By age 5, children can accurately estimate durations up to about 30 seconds
Even young infants possess mechanisms for measuring the duration of arbitrary intervals (e.g., the duration of a tone)

21. Duration discrimination
Expt vs. 4 sec
Success
Expt vs. 4.5 sec
Failure
Expt vs. 1 sec
Expt vs. 1 sec
6-month-old infants discriminate between tones of differing lengths at a 1:2 ratio, but not a 2:3 ratio.
Wynn & vanMarle, 2003

23. Space Infants tend to use egocentric representations
Can use allocentric system but early in development landmarks must be obvious and right next to object (~9mths)
Concepts like “next to” or “in between” emerge ~11 mths

24. Spatial Representation
Self-locomotion is important for understanding spatial relations
Examples:
Visual cliff studies (understanding of depth)
Gap studies
crawlers or infants using walkers remember objects’ locations better than non crawlers of same age.
toy hidden in 1 of 2 wells babies who crawled to the other side did better than those carried.
Driver vs. Passenger in a car analogy!

25. Spatial Representation
B = ~ 7%
C = ~ 7%
D = ~ 45%
2-year-olds encoded geometric landmarks but not featural ones even though featural information is more informative. Even rats and adults seem to have a preference for geometric cues over featural cues.
Hermer & Spelke, 1994, 1996

26. Dead Reckoning and ‘Mental Maps’
The ability to keep track of one’s location relative to the starting point and return directly back to it.
Rats, ants, and geese (and humans to some degree) can do it
2-year-olds show some dead reckoning abilities--if led on circuitous routes they can return to the starting point more often than chance (this typically increases over development somewhat)

27. Dead Reckoning and Other Spatial Skills
Sociocultural factors influence these abilities
(e.g. aboriginal desert dwellers over city-dweller, video gamers)
Gender differences favoring males (e.g. waterline on cup task)
Same/Mirror Image Tasks

28. Mental Rotation & Water-Level Tests

29. Causality
By 11 months, infants expect the size of an object to be related to the amount of force it can exert on another object.
Kotovsky & Baillargeon, 1994
Habituation
Test OR

30. Causality (con’t) Causal Relations
Tool Use
structural properties are causally related to tool’s function
(Chen & Seigler, 2000)
Figure 7.8, from text
2 1/2 year-olds select the appropriate tool for retrieving the toy more frequently than 1 1/2 year-olds.

31. Cause–effect relations
It’s easier to remember concepts and order of events if
they are causally connected
Hearing that wugs are well prepared to fight and gillies to flee helped preschoolers categorize novel pictures like these as wugs or gillies (Krascum & Andrews, 1998). In general, understanding cause–effect relations helps people of all ages learn and remember.

32. Causality (con’t) Causal Relations
Magic tricks - searching for causes
Most 3- and 4-year-olds do not understand the point of magic tricks. By age 5 fascinated by magic tricks because causal mechanism is hidden. (Rosengren & Hickling, 1994)
4- and 5-year-olds, but not 3-year-olds, will actively search for the cause of an apparent magic trick.
The “Why” stage begins…

33. Number is...
not a directly perceivable property of any individual object.
an abstract concept that applies to sets of items.
Numerical equality: realization that all sets of a certain number of objects have something in common is the most basic numerical understanding.

34. Numerical Discrimination
5-month-old infants can discriminate between pictures containing 1, 2, or 3 items.
They fail to discriminate larger sets in this way unless the difference between the sets is large enough.
Habituation
Test or or or or
… and so on
… and so on
Starkey, Spelke, & Gelman, 1990; Van Loosbroek & Smitsman, 1990)

35. Two core systems of number
Object tracking: up to 3 or 4 objects
Core System 2
Approximate representations of large numerosities

36. Infants’ Arithmetic
infants of 5 months seems to have a basic understanding of arithmetic.

37. Large number discrimination
6-month-old infants discriminate:
4 vs. 8, 8 vs. 16, 16 vs. 32
BUT NOT: 8 vs. 12, 16 vs. 24
For larger sets (more than 4 items):
Infants can discriminate values that differ by a 1:2 ratio, but not a 2:3 ratio.
(Xu, in press; Xu & Spelke, 2000; Xu, Spelke, & Goddard, 2000)

38. Habituation
Habituation
Test
Test

39. Habituation
Habituation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Test
Test . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

40. Number vs. Continuous Extent
Pitting number against continuous extent by manipulating the size of the objects in the outcomes.
+ = or
wrong # right #
right amount wrong amount
(Feigenson, Carey, & Spelke, 2002)

41. Counting Some facts… Most children can count to 10 by age 3
Most 5-year-olds can count to 100
Most children do not understand relative magnitudes (i.e., ordinality) of the different numbers between 1 and 10 until age 5.
e.g. that 6 apples is more than 4 apples.
Most children do not understand cardinality until age 5.
e.g. Give-a-number task
2-year-olds:1 (and more than 1)
2 and a half-year-olds: 1, 2, (and more than 2)
3-year-olds: 1, 2, 3, (and more than 3)
3.5- to 4-year-olds: all numbers

42. Gelman and Gallistel’s (1978) 5 Counting Principles
One-to-one correspondence
- each object receives a single number label
Stable order
- number list is always said in same order
Cardinality
- total number corresponds to last number word said
Order irrelevance
- objects can be counted in any order
Abstraction
- any set of individuals can be counted