U05 - Sensation & Perception Flashcards
(38 cards)
Color constancy
- Brain’s ability to recognize color of an object as being the same even under different lighting conditions
- Brain adjusts its perception of color to hold it constant, accounting for changes in lighting conditions & other contextual factors (e.g., shadow
Stimulus
- something that elicits a reaction from our sensory system
- Light (vision)§Sound waves (hearing)§Mechanical pressure, vibration, temperature, pain (touch)§Chemicals in food and drink (taste)§Airborne chemicals (smell
Sensation
process by which sensory organs detect environmental stimuli & convert them into electrical signals for the nervous system
- The process by which our sensory organs receive stimulus energies from the environment and transduce them into the electrical energy of the nervous system.
Transduction
- The transformation of sensory stimulus energy from the environment into neural impulses.
- E.g., light entering your eyes is converted into neural impulses by specialized cells
Perception
- brain’s interpretation of these electrical signals to create an internal representation of the world
Bottom-up vs top-down processing
bottom-up:
- Interpretation relies both on raw sensory data
top-down:
- our prior experience, knowledge & expectation
psychophysics
- study of the relationship between the physical qualities of stimuli (physics) and our mental experience of them (psyche)
- the physical qualities of of stimuli and our mental experience of those stimuli is called psychophysics
- physics for the external physical stimuli and psyche for for our mental experience
absolute threshold of awareness
- minimum amount of stimulus that can be detected at least 50% of the time
sensitivity
- Sensitivity in psychology refers to how good someone is at detecting a stimulus, like a sound, light, or touch.
- If you have high sensitivity, you can notice even small or faint stimuli. If you have low sensitivity, you need a stronger stimulus to detect it.
- sensitivity to the absolute threshold refers to the smallest amount of stimulus (like light, sound, or touch) that a person can detect 50% of the time. It’s the minimum level at which you become aware of something.
signal detection theory
- An approach to measuring thresholds that takes into account both the intensity of the stimulus and psychological biases for a more accurate assessment.
- how we make decisions under conditions of uncertainty, such as when we are listening for a faint sound or looking for a light in the distance
liberal bias and conservative bias (signal detection theory)
liberal:
- Higher rate of hits, but also false alarms
conservative:
- Lower rate of false alarms, but also hits
just-noticeable difference/difference threshold
- smallest difference between two stimuli that can be detected at least 50% of the time
- The minimum difference required between two stimuli for an observer to detect a difference half the time.
weber’s law/weber’s fraction
- as stimuli get larger, differences must also become larger in order to be detectable
- This means the bigger or stronger the original stimulus, the bigger the change needs to be for you to notice it.
- If you’re holding a 10-pound weight, you might notice a 1-pound increase (11 pounds total). But if you’re holding a 100-pound weight, you might need a 10-pound increase (110 pounds) to notice the difference.
- fraction: The exact ratio for each type of stimulus (like sound or weight).
adaptation
- stop noticing a stimulus that remains constant over time
properties of light
Wavelength: This is the distance between two peaks of a light wave. It determines the color of light. Shorter wavelengths are blue/violet, and longer wavelengths are red.
Amplitude: This is the height of the wave. It determines the brightness of the light. Higher amplitude means brighter light.
Frequency: This is how many waves pass a point in a second. Higher frequency means more waves and shorter wavelengths.
Wavelength = color
Amplitude = brightness
Frequency = how fast the waves are
structures of the eye
cornea
- transparent tissue covering front of eye, focuses light
iris
- opaque, colourful muscle encircling the pupil
pupil
- hole in the iris where light enters the eye
lens
- membrane at front of the eye that focuses incoming light on the retina
accommodation
- adjustments of the lens’s thickness by specialized muscles in order to change the degree to which it bends light
retina
- surface in the back of the eye containing receptor cells specialized for transducing light (photoreceptors)
photoreceptors (two kinds)
photoreceptors:
rod
- Photoreceptor cell that primarily supports nighttime vision
cone
- Photoreceptor cell that is responsible for high-resolution color vision
visual transduction
- the process by which light is converted into electrical signals in the eye so that the brain can understand and interpret what we see
- Light enters the eye and hits the retina at the back of the eye.
- The retina has special cells called photoreceptors (rods and cones).
…Rods help you see in low light and black-and-white.
….Cones help you see colors in bright light. - When light hits these cells, it triggers a chemical change that creates an electrical signal.
- This signal is sent through the optic nerve to the brain, where it is processed as an image.
rhodopsin
- a light-sensitive protein found in the rod cells of the retina in your eye. It helps you see in low-light conditions.
color vision
- comes from cones
- Each cone has one of three distinct varieties of photopigment§Sensitive to short, medium, or long wavelengths (approximately corresponding to blue, green, or red)
- These cones work together to help you see a full range of colors. When light hits the cones, they send signals to your brain based on the combination of red, green, and blue light they detect. The brain then mixes these signals to produce the color you see.
- If red and green cones are activated, you see yellow.
If all three (red, green, blue) cones are activated equally, you see white.
In short, color vision is made possible by cones in the eye that detect red, green, and blue light, allowing your brain to mix and perceive different colors.
trichromatic theory
- the three types of cone cells work together to produce perception of colour
opponent-process theory
- stating that information from the cones is separated into three sets of opposing or opponent channels in the ganglion cell layer.
- explains color afterimages as perceptual opposites, originating from opposite sides of the color circle
visual system is described as “hierarchical”
- The brain processes and organizes the data it receives from the retina through hierarchical series of steps of increasing complexity
how visual info travels from the eyes to the brain
light hits the eye, turns into signals, travels thru the optic nerve, reaches the brain, processed into a pic
