Sensation and Perception

Sensation and Perception If a tree falls in the woods and no one is around to hear it, does it make a sound?

Sensation vs. Perception • Sensation • The experience of sensory stimulation • “I see…hear…feel…smell…taste something” • Raw sensory information • Perception • The process of creating meaningful patterns from raw sensory information • “I see a cat;” “I hearfootsteps” etc. • Forms the foundation of consciousness

The Nature of Sensation

The Basic Process • Is the same for most senses: • Energy stimulates receptor cell in one of the sense organs • If stimulus is strong enough, a signal is sent by receptor through sensory nerves (we know what these are) to appropriate area of cerebral cortex (we also know what this is)

The Basic Process • Receptor cells • Specialized cells that respond to a particular type of energy • These exist in your sense organs • Doctrine of specific nerve energies (Muller) • One-to-one relationship between stimulation of a specific nerve and the resulting sensory experience • For example, applying pressure with your finger to your eye results in a visual experience because they are visual receptors– try it!

How does the brain differentiate between variations of same sensory mode???? • Aka, how do we know the difference between an ambulance siren and a song on our ipod (they’re both sounds and stimulate the same organ, no?) • Answer: Different stimuli affect: • How many neurons fire • Which neurons are activated or inhibited • The rate at which the neurons fire • This information acts as a code for your brain to crack.

Sensory Thresholds • Absolute threshold • The minimum amount of energy that can be detected 50% of the time • If the responders can identify a sound 50% of the time they hear it, that’s the absolute threshold • E.g. At what point can you hear the presence of a sound? (Watch example)

Absolute Thresholds • Taste: 1 gram (.0356 ounce) of table salt in 500 liters (529 quarts) of water • Smell: 1 drop of perfume diffused throughout a three-room apartment • Touch: the wing of a bee falling on your cheek from a height of 1cm (.39 inch) • Hearing: the tick of a watch from 6 meters (20 feet) in very quiet conditions • Vision: a candle flame seen from 50km (30 miles) on a clear, dark night

Sensory thresholds • Difference threshold • The smallest change in stimulation that can be detected 50% of the time • Also called the just noticeable difference • e.g. At what point can you tell that the TV volume has been raised?

Sensory Thresholds • Weber’s Law • States that the difference threshold is a constant proportion of the specific stimulus • Senses vary in their sensitivity to changes in stimulation • Example: Would you feel an additional 5 points on each side of barbell when you’re benching 200 lbs? What if you’re benching 100?

Sensory Thresholds • Sensory adaptation • An adjustment of the senses to the level of stimulation they are receiving • Car radio blasting? • Toothpaste/orange juice (ice cream/soda) phenomenon? • “sweet” taste buds adapt (become less sensitive) • Other examples? • Perfume, Swimming/Baths, etc.

Subliminal Perception • The notion that we may respond to stimuli that are below our level of awareness • Research shows that the effect only occurs in controlled laboratory studies • Research outside the laboratory shows no significant effect of subliminal information • Subliminal Research@Duke University • Subliminal Advertising Experiment • Subliminal McDonald's Advertisement

Extrasensory Perception • Refers to extraordinary perception such as • Clairvoyance – awareness of an unknown object or event • Telepathy – knowledge of someone else’s thoughts or feelings • Precognition – foreknowledge of future events • Research has been unable to conclusively demonstrate the existence of ESP

Vision

The Visual System • Cornea • Transparent protective coating over the front of the eye • Pupil • Small opening in the iris through which light enters the eye • Iris • Colored part of the eye

The Visual System • Lens • Focuses light onto the retina • Retina • Lining of the eye containing receptor cells that are sensitive to light • Fovea • Center of the visual field

Receptor Cells • Cells in the retina that are sensitive to light • Visual receptors are called rods and cones

Receptor Cells • Rods • About 120 million rods • Respond to light and dark • Very sensitive to light • Provide our night vision • Cones • About 8 million cones • Respond to color as well as light and dark • Work best in bright light • Found mainly in the fovea

Receptor Cells • Bipolar cells • Receive input from receptor cells • Ganglion cells • Receive input from bipolar cells • Blind spot • Area where axons of ganglion cells leave the eye

Adaptation • Dark adaptation • Increased sensitivity of rods and cones in darkness • Light adaptation • Decreased sensitivity of rods and cones in bright light • Afterimage • Sense experience that occurs after a visual stimulus has been removed

From Eye to Brain • Optic nerve • Made up of axons of ganglion cells • carries neural messages from each eye to brain • Optic chiasm • Point where part of each optic nerve crosses to the other side of the brain

Properties of color Hue – refers to colors such as red and green Saturation – refers to the vividness of a hue Brightness – the nearness of a color to white Color Vision

Theories of Color Vision • Additive color mixing • Mixing of lights of different hues • Lights, T.V., computer monitors (RGB) • Subtractive color mixing • Mixing pigments, e.g., paints

Theories of Color Vision • Trichromatic theory • Three different types of cones • Red • Green • Blue-violet • Experience of color is the result of mixing of the signals from these receptors • Can account for some types of colorblindness

Forms of Colorblindness • Approximately 10% of men and 1% of women have some form of colorblindness • Dichromats • People who are blind to either red-green or blue-yellow • Monochromats • People who see no color at all, only shades of light and dark

Theories of Color Vision • Trichromatic theory cannot explain all aspects of color vision • People with normal vision cannot see “reddish-green” or “yellowish-blue” • Color afterimages

Theories of Color Vision • Opponent-process theory • Three pairs of color receptors • Yellow-blue • Red-green • Black-white • Members of each pair work in opposition • Can explain color afterimages • Both theories of color vision are valid

Color Vision in Other Species • Other species see colors differently than humans • Most other mammals are dichromats • Rodents tend to be monochromats, as are owls who have only rods • Bees can see ultraviolet light

Hearing

Sound • Sound waves • Changes in pressure caused by molecules of air moving • Frequency • Number of cycles per second in a wave, measured in Hertz (Hz) • Frequency determines pitch

Sound • Amplitude • Magnitude (height) of sound wave • Determines loudness, measured in decibels (dB) • Overtones • Multiples of the basic tone • Timbre • Quality of texture of sound

The Ear • Eardrum • Middle ear • Contains three small bones; the hammer, anvil, and stirrup • These bones relay and amplify the incoming sound waves

The Ear • Oval window • Membrane between middle ear and inner ear • Cochlea • Part of inner ear containing fluid that vibrates • This causes the basilar membrane to vibrate

The Ear • Basilar membrane • Membrane in the cochlea which contains receptor cells, called hair cells • Auditory nerve • Connection from ear to brain • Provides information to both sides of brain

Theories of Hearing • Place theory • Pitch is determined by location of vibration along the basilar membrane • Frequency theory • Pitch is determined by frequency hair cells produce action potentials • Volley Principle • Pattern of sequential firing determines pitch

Hearing Disorders • About 28 million people have some form of hearing damage in the U.S. • Can be caused by • Injury • Infections • Explosions • Long-term exposure to loud noises

The Other Senses

Smell • Detecting common odors • Odorant binding protein is released and attached to incoming molecules • These molecules then activate receptors in the olfactory epithelium • Axons from those receptors project directly to the olfactory bulb

Smell • Women have a better sense of smell than men • Anosmia • Complete loss of the ability to smell

Smell • Pheromones • Used by animals as a form of communication • Provides information about identity • Also provides information about sexual receptivity • Pheromones stimulate the vomeronasal organ (VNO) • Information from the VNO is sent to a special part of the olfactory bulb used for pheromonal communication

Taste • Four basic tastes • Sweet • Salty • Sour • Bitter • Recent discovery of fifth taste • Umami

Taste • Receptor cells are located in taste buds • Taste buds are located in papillae on the tongue • Chemicals dissolve in saliva and activate receptors

The Other Senses

Kinesthetic Senses • Kinesthetic senses provide information about speed and direction of movement • Stretch receptors sense muscle stretch and contraction • Golgi tendon organs sense movement of tendons

Vestibular Senses • Vestibular senses provide information about equilibrium and body position • Fluid moves in two vestibular sacs • Vestibular organs are also responsible for motion sickness • Motion sickness may be caused by discrepancies between visual information and vestibular sensation

The Skin Senses • Skin is the largest sense organ • There are receptors for pressure, temperature, and pain • Touch appears to be important not just as a source of information, but as a way to bond with others

The Skin Senses • Homunculus Man • Proportional representation of skin receptor concentration • The larger the part, the more receptors/the more sensitive

Wahhhh, mommyyy Pain • Serves as a warning about injury or other problem • Large individual differences in pain perception • Gate control theory • Neurological “gate” in spinal cord which controls transmission of pain to brain

Sensation and Perception