Transcript Slide 1
Memory Memory Memory is the capacity to retain information over time (in both living organisms and computers). There is no single memory system in our brain but several, functionally distinct systems. They differ in • the type of information that they store, • the duration for which it is stored, and • the maximum amount of information that can be stored (capacity). The psychology of memory: two pioneers... William James Hermann Ebbinghaus History of the STS/LTS distinction 1890 - William James draws distinction between primary and secondary memory. PRIMARY MEMORY SECONDARY MEMORY Reward portion of present space of time Linked to conscious experience Genuine past Unconscious - permanent Retrieval is effortless Retrieval is effortful The development of computers in the 1960s provided another analogy which split memory into two: CPU/RAM = STS, STORAGE = LTS Modal model of memory developed by Atkinson & Shiffrin (1968) The modal model of memory Sensory Rehearsal Store Sensory Store Short Long Term Term Store Store Transfer Sensory Store Displacement (Forgetting) But what is the evidence for separate STS / LTS? The Modal Model (Atkinson & Shiffrin) STIMULUS INPUT e.g. Visual (iconic) Auditory (echoic), etc. Some Control Processes: Rehearsal, Coding, Decisions, Retrieval Strategies Sensory Memory RESPONSE OUTPUT Short-term Memory RETRIEVAL ENCODING Long-term Memory Sensory Memory Sensory memory is a “short-term storage facility” for incoming sensory information. Holds information only long enough for higher-level cognitive processes to operate on it, e.g., object recognition. There is one separate form of sensory memory for each of the five senses, for example: • Iconic memory: visual sensory memory holding a “snapshot” of recent (200-300 ms) visual input. • Echoic memory: auditory sensory memory “echoing” recent (several seconds) auditory input. Iconic Memory Experiment Sperling (1963): 43 array of randomly chosen English letters • Whole-report condition: • After brief presentation, letters disappear • Subjects have to report which letters were shown • Partial-report condition: • After brief presentation, letters disappear • The pitch of a played tone indicates whether to report the letters in the first, second, or third row. Iconic Memory Experiment Whole-Report Condition Your task: Memorize as many letters as possible in the following display and report them after the display has disappeared. Iconic Memory Experiment Iconic Memory Experiment HBXV MFZT PGWQ Iconic Memory Experiment Iconic Memory Experiment How many letters did you remember? Typically, people can report only 4 or 5 of them correctly. Iconic Memory Experiment Partial-Report Condition Your task: Memorize as many letters as possible in the following display. Right after the display has disappeared, an arrow will point to one of the previously shown rows. Report as many letters as possible that were shown in that row. Iconic Memory Experiment Iconic Memory Experiment EYHN GXKF MQZT Iconic Memory Experiment Iconic Memory Experiment Iconic Memory Experiment How many letters did you remember this time? Often, people can report all four letters. Iconic Memory Experiment Partial-Report Condition Let us do the partial-report condition one more time, in case you were not prepared the first time. Iconic Memory Experiment Iconic Memory Experiment KCRQ PVZG LHXS Iconic Memory Experiment Iconic Memory Experiment Iconic Memory Experiment You did not know where the arrow was going to appear; therefore, you must have memorized all 12 letters in order to get all four relevant letters right. The Sperling experiment thus shows that iconic memory can hold at least 12 letters. Other research shows that in fact iconic memory can hold much more information – a quite detailed “snapshot” of the visual scene. However, this information fades very quickly (fast decay). Working Memory Working memory is also known as short-term memory. It can hold information for longer durations than sensory memory. However, its capacity is severely limited. Working memory can hold multimodal information, i.e., acoustic and visual information. Example: Dialing a phone number that somebody has just told us. Working Memory Store • What happens if you need to keep information in working memory longer than 30 seconds? • To demonstrate, memorize the following phone number (presented one digit at a time): 857916 3 Working Memory Store • What is the number? 857-9163 The number lasted in your working memory longer than 30 seconds So, how were you able to remember the number? Maintenance Rehearsal • Mental or verbal repetition of information allows information to remain in working memory longer than the usual 30 seconds Maintenance Rehearsal Sensory Input Sensory Memory Attention Working or Short-term Memory Maintenance Rehearsal • What happens if you can’t use maintenance rehearsal? • Memory decays quickly • To demonstrate, again memorize a phone number (presented one digit at a time) – BUT, have to count backwards from 1,000 by sevens (i.e., 1014, 1007, 1000 … etc.) 628509 4 Working Memory Store • What is the number? 628-5094 Without rehearsal, memory fades Peterson’s STM Task • Test of memory for 3letter nonsense syllables • Participants count backwards for a few seconds, then recall • Without rehearsal, memory fades 100 Percentage 90 who recalled 80 consonants 70 60 50 40 30 20 10 0 3 6 9 12 15 18 Time in seconds between presentation of consonants and recall request (no rehearsal allowed) Working Memory Store • What happens if you need to remember more than 7 +/- 2 items? • To demonstrate, memorize the following 16 digit number (presented one digit at a time): 1492181219982001 Working Memory In a famous paper, Miller (1956) studied the capacity of working memory. He found that people can hold about seven plus/minus two items in working memory. The problem is: How do you define “item?” For example, expert chess players can store entire game configurations in working memory. Chess novices can memorize the positions of at most a few pieces. What is the reason for this? Differences in working memory? Chunking • Grouping small bits of information into larger units of information – expands working memory load • Which is easier to remember? –4 8 3 7 9 2 5 1 6 – 483 792 516 Working Memory Chunking TMCAIADMKSPJDINC TMC AIADMK SP JD INC Coding in WM Conrad’s experiment (1964) Letters presented visually Asked to recall immediately Errors like A for K ; E for P Acoustic coding Wicken’s expt. (1972) Elements of same semantic categories overlap Semantic Coding Visual Coding Recall time varies with spatial orientation Three-Box Model of Memory Long-Term Memory You can still remember events that happened a long time ago, for example, when you were a child. Long-term memory is able to store large amounts of information over very long durations. There are several distinct types of long-term memory: • Procedural memory (Implicit Memory) • Declarative memory (Explicit Memory) • Semantic memory • Episodic memory Long-Term Memory Store • Once information passes from sensory to working memory, it can be encoded into long-term memory Maintenance Rehearsal Sensory Input Encoding Sensory Memory Attention Long-term Working or memory Short-term Memory Retrieval Procedural Memory • Also called implicit memory • Memory for skill • Demonstrated only by doing • Arises without conscious recall • Examples: Riding a bike, playing tennis, playing the piano. Declarative Memory • Memory for facts and events • Demonstrated by speaking • Arises with conscious recall • Semantic memory: • Knowledge of facts • For example, things that you learn in this course • Episodic memory: • Contains personally experienced events • E.g., what you did on your birthday last year. How long does it last % recall 1 yr 3 yr Time 50yr Remembering Over Years • Marigold Linton tested her own memory for personal events over a period of several years. • Retention fell at a gradual but steady rate. Long-Term Memory Store • Function - organizes and stores information – more passive form of storage than working memory • Unlimited capacity • Duration - thought by some to be permanent Maintenance Rehearsal Sensory Input Encoding Sensory Memory Attention Long-term Working or memory Short-term Memory Retrieval Long-Term Memory Store • Encoding - process that controls movement from working to long-term memory store • Retrieval - process that controls flow of information from long-term to working memory store Maintenance Rehearsal Sensory Input Encoding Sensory Memory Attention Long-term Working or memory Short-term Memory Retrieval Encodings • Different formats • Implicit Memory Production rules – Neural locus of production rules is cerebellum • Explicit Memory Network of connected nodes – Distributed most likely throughout entire cortex and other areas. Conceptual Grid a memory test... DOORKNOB CONCRETE SUNSHINE RAILROAD SOFTBALL HAMMER CURTAIN DOCTOR SUBWAY CANDLE FOLDER TURKEY COFFEE PLAYER LETTER TOWEL KITTEN MAPLE PENCIL TABLE Serial Position Effects no distractor task distractor task • In free recall, more items are recalled from start of list (primacy effect) and end of the list (recency effect) • Distractor task (e.g. counting) after last item Serial-Position Effect • The tendency for recall of first and last items on a list to surpass recall of items in the middle of the list. Serial Position Effects • Explanation from Atkinson and Shiffrin (1968) model: – Early items can be rehearsed more often more likely to be transferred to long-term memory – Last items of list are still in short-term memory (with no distractor task) they can be read out easily from short-term memory How We Remember Effective Encoding Rehearsal Mnemonics Rehearsal • Maintenance Rehearsal: Rote repetition of material in order to maintain its availability in memory. • Elaborative Rehearsal: Association of new information with already stored knowledge and analysis of the new information to make it memorable. Why We Forget Decay Replacement Interference Cue-dependent Forgetting Psychogenic Amnesia Decay • Decay Theory: The theory that information in memory eventually disappears if it is not accessed; it applies more to short-term than to long-term memory. Interference • Retroactive Interference: Forgetting that occurs when recently learned material interferes with the ability to remember similar material stored previously. • Proactive Interference: Forgetting that occurs when previously stored material interferes with the ability to remember similar, more recently learned material. Cue-dependent Forgetting • Cue-Dependent Forgetting: The inability to retrieve information stored in memory because of insufficient cues for recall. • State-Dependent Memory: The tendency to remember something when the rememberer is in the same physical or mental state as during the original learning or experience. Psychogenic Amnesia • The partial or complete loss of memory (due to nonorganic causes) for threatening information or traumatic experiences. Evaluating Modal Memory Model • Pro: provides good quantitative accounts of many findings • Contra: – assumption that all information must go through STM is probably wrong – Model proposes one kind of STM but evidence suggests we have multiple kinds of STM stores Cognitive Architecture of Memory • Incorporates more details • Processing power in memory ACT* Model: Adaptive Control of Thought (Anderson) External Environment Encoding Performance Working Memory Storage Match Retrieval Declarative Memory Execution Production Memory The Working Memory Model (Baddeley) Visuo-spatial Sketchpad Processing of Visual Information Executive Control System Supervises and controls processes Articulatory Loop Rehearsal and processing of auditory information Working Memory Model • Baddeley (1992) • 3 interacting components Visuospatial Sketch Pad Central Executive Phonological Loop Working Memory Model • Visuospatial sketch pad - holds visual and spatial info • Phonological loop - holds verbal information • Central executive - coordinates all activities of working memory; brings new information into working memory from sensory and long-term memory Visuospatial Sketch Pad Central Executive Phonological Loop Baddeley’s working memory model Baddeley proposed replacing unitary short-term store with working memory model with multiple components: • Phonological loop • Visuo-spatial sketchpad • Central executive (ignore the episodic buffer) Baddeley and Hitch (1974) Baddeley (1986) Phonological Loop (a.k.a. articulatory loop) • Stores a limited number of sounds – number of words is limited by pronunciation time, not number of items • Experiment: LIST 1: Burma Greece Tibet Iceland Malta Laos LIST 2: Switzerland Nicaragua Afghanistan Venezuela Philippines Madagascar Reading rate determines serial recall • Reading rate seems to determine recall performance • Phonological loop stores 1.5 - 2 seconds worth of words Working memory and Language Differences • Different languages have different #syllables per digit • Therefore, recall for numbers should be different across languages • E.g. memory for English number sequences is better than Spanish or Arabic sequences (Naveh-Benjamin & Ayres, 1986) Two routes to phonological loop Visual presentation Auditory presentation Articulatory control process Speech code Phonological loop • Articulatory control process converts visually presented words into a speech code • Articulatory suppression (e.g. saying “the” all the time) – disrupts phonological loop – diminishes word length effect with visual presentation (visiospatial sketchpad takes over) Immediate word recall as a function of modality of presentation (visual vs. auditory), presence vs. absence of articulatory suppression, and word length. Baddeley et al. (1975). Neural Network Models of Memory • Long-term memory: - weight-based memory; the memory representation takes its form in the strength or weight of neural connections • Short-term memory: - activity-based memory, in which information is retained as a sustained or persistent pattern of activity in specific neural populations Weight-based memory • Long-term associative memories can be formed by Hebbian learning: changes in synaptic weights between neurons Donald O. Hebb Working Memory and Prefrontal Cortex Delayed Match to Sample Tasks • Correct response requires keeping location of food in mind. • Monkeys and humans w/lesions of PFC fail these tasks. • Infants younger than 12 months also fail versions of these tasks. The Hippocampus Memory Learning Navigation THE HIPPOCAMPUS = Dentate Gyrus, CA1-CA3, & Subiculum Marjor input from Entorhinal Cortex which is other brain areas such as the Prefrontal Cortex Information Flow: Entorhinal Cortex Dentate Gyrus CA3CA1 Subiculum Neurogenesis: birth of new neurons Highly active throughout development Also adult hippocampal neurogenesis (dentate gyrus)! What might this mean for learning and memory? Hippocampal Damage • Retrograde Amnesia: loss of memories before damage to the hippocampus • Anterograde Amnesia: inability to form new memories • Some causes: aging, Alzheimer’s disease, stress, temporal lobe epilepsy Patient H.M. Patient H.M. After Surgery for Temporal Lobe Epilepsy Anterograde Amnesia: Intact working and procedural memory Could not commit to long-term SOME Retrograde Amnesia: Couldn’t remember 3–4 -day prior to surgery, + some events up > 11 years prior Able to commit new motor skills to long-term memory without actually remembering learning them http://images.google.com/imgres?imgurl=http://dspace.mit.edu/bitstream/handle/1721.1/45580/9-10Spring-2004/NR/rdonlyres/Brain-and-Cognitive-Sciences/9-10Spring-2004/8AFEA93F-9C52-42E5-B967211CCD2AA287/0/chp_9_10_hip_enc.jpg&imgrefurl=http://dspace.mit.edu/bitstream/handle/1721.1/45580/9-10Spring-2004/OcwWeb/Brain-and-Cognitive-Sciences/9-10Spring2004/CourseHome/index.htm&usg=__baapQ1i44dpgT7ZDQuuBuOVnwnw=&h=307&w=350&sz=26&hl=en&start=2&um=1&tbnid=n5pajUYXebb7tM:&tbnh=105&tbnw=120&prev=/images%3Fq%3Dcoronal%2Bhippocampal%2Bhuman%26hl%3Den%26client%3Dfirefoxa%26rls%3Dorg.mozilla:en-US:official%26sa%3DG%26um%3D1