lecture notes—first midterm Flashcards

Question

Manipulating Variables | Empirical

Answer 1

* experimental research is how we control variables in order to test for causation; causation affords explanation. * causation and the method of differences (lecture 1); **independent variable** and **dependent variable**. * main problem is how do you manipulate just one variable? * e.g. does sleep deprivation cause memory failure? * could be unfamiliar environment, so you want to make sure that an **alternative explanation** is ruled out. * this is controlling for a confounding variable. * placebo effect is the classic example of a **confounding variable**.

Answer 2

* **between-subject design**; there is the experimental group and the control group. * a lot of what is published should be held in question because a lot of the time there is no relevant control group to compare the results to. * e.g. sleep deprivation experiment. * have two groups, one group in the lab getting sleep and then being tested for memory failure, and the other group also in the lab but also sleep deprived and then test for memory failure. * so the only relevant difference between them is the amount of sleep. * if there are differences in the memory tests it is plausible (not certain) that the difference is due to sleep differences. * **random assignment** and other sources of variability evenly spread across conditions. * you have to do a lot to make sure that it’s not placebo.

Answer 3

* **within-subjects design**: the same participants experience all types of stimuli or experimental conditions. * e.g. in the lab with and without sleep. * here, the **order of conditions** needs to be randomly assigned so that you are testing the independent variable and not the change between the experimental condition and the control condition.

Answer 4

* main problem with experimental method is that as we control variables we make the laboratory situation more and more artificial and we lose ecological validity (inescapable trade-off). * important role of **theoretical argumentation** and establishing the **plausibility of the interpretation** of the experimental data, i.e. arguing for the relevance of the differences between the experimental situation and the real world. * the degree to which the experimental result affords consistent and powerful intervention in the real world provides evidence for ecological validity.

Answer 5

* dealing with sampling bias is the main job of statistics. * random assignment is important but there’s important information in the sample that can be used to assess how accurate it represents the population. * information about **distribution**, **central tendency**, and **variability** are important for determining this. * **distribution** of the data; two pieces of information are whether some scores occurred more often than others and whether all scores were more clumped in the middle or more evenly spread across the whole range. * **normal distribution**, **negatively skewed** distribution, and **positively skewed** distribution. * generally, results are better when you have a normal distribution (that’s why it’s called normal) * **central tendency**, **mode**, **mean**, and **median**. * **variability**, **standard deviation**, **hypothesis testing**. * usually differences between the experimental group and the control group. * trying to show that the most likely explanation for differences is due to your manipulation of the variable. * problem arises when there is overlap between the sets of results for both groups, this is the signal to the noise problem talked about in lecture 1. * overlap means those results are ambiguous, i.e. either the point to the role of the independent variable or point to an alternative variable (possible confound) that the experimenter tried/failed to control. * i.e. ambiguity means that an alternative explanation has not been ruled out; no clear information. * scientists use **statistical significance** to address the problem of overlap/ambiguity/no clear information. * use a measure of central tendency (usually the mean) and a measure of variability (usually standard deviation) to calculate how much the difference could be due to chance. * 5% rule—if there’s only a \<5% that it could’ve been caused by chance, then it’s probably not caused by chance; if it’s 10% then it may have been chance. * one problem with statistics: multiple comparison means that the more likely you will luck out and get a fluke result because 5% of the difference will be produced by chance. * yet the experimenter will conclude that it was due to the manipulation of the independent variable. * one response is to raise the standard as you increase the number of times you make the comparison, e.g. only accept answers where the chances of the difference being produced by luck are 1% etc. * second problem: as you increase the number of participants, then small differences between groups become more and more statistically significant. * an alternative is **power analysis**: you do not just answer the yes-no question of whether or not the difference is significant; you also answer the question as to how large the difference is—how much of a difference does the manipulation of the independent variable actually make.

Answer 6

* **resting potential**, the **electrostatic gradient**, and the **concentration gradient** * ions and movement across the membrane * the **action potential** and how it travels down the axon * the **refractory period** * **fire together wire together** principle—not enough to explain how neural networks learn, but is a foundational principle * patterns of activity are connected to patterns of connectivity * how our brain is connected affects how it fires, and how our brain fires affects how it wires * layers of learning: brain is modeling itself as it models the world * the brain isn’t just interested in predicting the world, but predicting the other parts of your brain * bottom up processing and top down processing * e.g. I have to read the word to read the letters, but I have to read the letters to read the word, so reading is impossible * the brain is dynamically interacting with itself in a layered fashion * 1988; one of the first computers was made that could read text * we’re now getting AI that can understand spoken text * patterns of patterns * why is the brain wired in such a complex way? * your brain is not just an electrochemical processing, but a gland that’s responding to tons of chemicals that are diffusing through the body and the brain * the full array of neurotransmitters and their functions is extremely complex, with many variations of NTs, many functions, many interactions and different scales * Siegel’s brain in the hand * your fist is the brain and your wrist is the brain stem * cerebellum has a lot to do with fine tuning the parts of your cortex * looks for complex patterns and looks for ways to process those patterns * you have more neurons in your cerebellum than cortex * being exacted to help the frontal cortex with balance * kind of like a second brain that helps model the primary brain * evolutionary direction of function and morphology (back to front, inside to outside) * brainstem/hindbrain, sub-cortical regions, cerebellum, 4 lobes of the cortex, pre-frontal cortex

Answer 7

* important neurotransmitters and their key “functions” * neurotransmitters can have extremely different functions depending on where thy’re used * PNS vs. CNS: muscle/motor vs. higher cognition, plasticity, Alzheimer’s, etc. * clinical depression is very complex; antidepressants work only 30% better than placebo * you are the plaything of chemical gods, with your “self” and its thoughts, feelings and actions all being conditioned, shaped, influenced, driven by fluctuating levels of chemical neurotransmitters * your brain is also glandular and affected by body’s hormonal system * so not only neurons wiring-firing also the chemical environment in which is occurs, which is effected by the neurotransmitters released and hormones of the endocrine system * hardware, software, and wetware of the brain * VTA released dopamine into the nucleus accumbens, amygdala, prefrontal cortex, etc. * studied by Fisher 2006 * intense love * super-salience * attention—if you’re in love, the person should be able to get your attention * attachment—you will miss or grieve for them * motivation—you want to be together with them * similarity of intense love to other phenomena gives us clues to other dopamine based behaviour * learned helplessness * compulsive behaviour * addiction * depression * the very salience-reward processes so central to learning and love make us so susceptible to self-destructive behaviour as well; our existence is tragic in this sense * attachment and love is very important to convince you to raise babies

Answer 8

* why two hemispheres with different functions? * a lot of redundancy and plasticity * in general, how are they organized to function? it’s not intrinsic * first a caution about localizing function * two very different problem solving situations: * familiar well defined situations * left hemisphere; narrow focus of attention; step-by-step process; if you can zero your attention in and notice different details, you have to have fine motor skills to engage with it * our culture tends to overemphasize the left hemisphere * unfamiliar ill defined situations * right hemisphere; wide open attention; tolerant of ambiguity (you don’t go “I’m not doing something until I know for sure it’s a predator); you want to get the gist and react all at once; parallel vs. step-by-step * Navon letters; an H made up of Ls * with left hemisphere damage, people draw a whole H * right hemisphere damage, people draw individual Ls * Jill Bolte-Taylor, *My Stroke on Insight* * had a stroke, and her left hemisphere shut off and she felt it happening slowly * insight problem solving (refer to the 9-dot problem) * when you have an insight, (an “aha” moment; when you realize you can go out of the square) activity that was dominant in the left shifted to the right hemisphere * transcranial direct current stimulation * two electrodes and a 9-V battery; running a weak electrical current changes the probability of certain neurons firing * by doing this, they could triple the number of insight problems people solved. * when people had this put on their head, the probability of being able to solve this without help went from 0% to 40% (this has a 1 in a billion chance of happening by random) * this means you can do the opposite; put the opposite montage and decrease your brain activity—what if governments could have this power to do this wirelessly? * “although many of us may think of ourselves as thinking creatures that feel, biologically we are feeling creatures that think” * split brain experiments * does this produce two people? (two smaller brains) * where are you? * your self is constructed just like the world of everyday experience

Answer 9

* possibility of being a zombie: the case of blindsight * case of a 53 year old doctor with complete cortical blindness, reading emotion expressions because of a functioning amygdala * you can bring them into a room and tell them to point to the chair in the room (tell them to guess); and they can point to where the chair is * you can get powerful things happening without conscious awareness * highway hypnotism; when you’ve been driving for a really long time and you haven’t been paying attention to the road at all—you’re doing a very complex thing without conscious awareness * what is consciousness for? what is the difference between an unconscious mental state and a conscious one? * Baars: consciousness may be a global workspace; says what it does but not really what it is * Tononi: consciousness may be integrated information; says what it is but not what it does * we need an answer that unifies the function and nature together * Ramachandran: consciousness and the salience landscape * individuals differ in terms of their salience landscape * Bor and Seth: consciousness as prefrontal parietal network—chunking, restricting, and insight. consider the spontaneous shifting in and out of consciousness of the Necker cube * the prefrontal cortex seems to be the center of the higher cognitive, reflective, and rational processes, that makes us human, i.e. capable of rationality, morality, long term goals, behavioural flexibility, and perhaps consciousness? * consider *Phineas Gage* * he had a metal rod go in through his cheek and through his brain; prefrontal cortex was damaged * it would be rash to attribute too much to the prefrontal cortex and its rationality * Damasio and *Descartes’ Error* * emotions and the sculpting of the salience landscape—undamaged prefrontal cortex but damaged emotional center, didn’t become perfect angels * if you lose your emotions, you won’t become perfectly rational, you’ll collapse * they could score perfectly on an IQ test, but would break down if you asked them whether they wanted to write the test with a red or blue pen * emotions and the framing of experience * what you care about and how you care about it are what make you rational * Montague, *Your Brain is Almost Perfect* * the main difference between you and a computer * computers can process way more information than us and way more logically * but the computer doesn’t care about the information it processes, some of the information is more salient to you than other * the ability to use emotions to sculpt your salience landscape is what makes you so intelligent * pay attention to all the parts of the limbic system and what they do

Answer 10

* the biology of the brain reveals that the brain is a machine of machines interacting in complex self-organizing processes * the brain is a machine of machines that can make itself into a new kind of machine * neuroplasticity; synaptogenesis and neurogenesis—change in competence not just content (how you know not what you know)