Aim What are the steps in the visual

Aim: What are the steps in the visual process? DO NOW: • Take out your HW- p. 19 - 20 • What are the 5 senses? How are they alike? Different? HW: • None

How our Senses are Alike • Vision, hearing, smell, taste, touch, pain and body position are all similar for three reasons. – First, they all transduce stimulus energy into neural impulses. – Second, they are all more sensitive to change than to constant stimulation (habituate). habituate – Third, they all provide us with information about the environment we are in.

Sensory Receptors Name the category for each (photoreception, mechanoreception, or chemoreception)

Categories of Sense Organs and Sensory Receptors sensory receptors – specialized cells that detect stimulus information and transmit it to sensory (afferent) nerves and the brain – TYPES • photoreception – detection of light – perceived as sight • mechanoreception –detection of pressure vibration, and movement – perceived as touch, hearing and equilibrium • chemoreception – detection of chemical stimuli – perceived and smell and taste

What is Transduction? • Conversion of one form of energy into another – i. e. change stimulus energies, such as sights, sounds, and smells, into neural impulses our brains can interpret • Light • Vision (Retina) • Sound Waves • Hearing (Cochlea) • Pressure, heat, cold • Touch (Skin) • Chemical • Taste (Tongue) • Smell (Olfactory Bulb) • Chemical • Vestibular (Balance) • Receptors in inner ear • Kinesthetic (body position and • Receptors in muscles movement)

How Our Senses are Different • Each sense taps a different form of stimulus, and sends the information it gathers to a diff. part of the brain. • Each senses extracts different information and sends it to its own specialized processing are in brain.

Synesthesia • an experience in which one sense (say, sight) induces an experience in another sense (say, hearing) – Possible Outcomes: see music, taste color

Fun Facts About Vision • Click for article

Structure of the Eye

Acuity- the sharpness of vision Light rays from distant objects focus in front…when image reaches the back, the rays spread out creating a blur. Light rays from near objects focus behind the retina creating a blur.

• • • Steps in Transduction Concept Map Watch Video & Add to Concept Map Bipolar cells • • Cones • Cornea Ganglion cells • • Iris Lens • Rods Light wave • retina Pupil Occipital lobe Optic nerve https: //www. youtube. com/watch? v=g. Bdy. U 1 b 0 ADQ

Retina’s Reaction to Light- Receptors **Rods are more sensitive to light than the cones which is why the world looks colorless at night. Cones – near center of retina (fovea) – fine detail and color vision – daylight or well-lit conditions Rods – peripheral retina – detect black, white and gray – twilight or low light **Nocturnal animals such as mice, toads, rats and bats have retinas made up almost entirely of rods.

Vision- Receptors in the Human Eye Cones Rods Number 6 million 120 million Location in retina Center Periphery Sensitivity in dim light Low High Color sensitive? Yes No

Aim: What are the steps in the visual process? DO NOW: • Check for Understanding p. 31 HW: Read “ Watch out for Visual Cliff” packet pps. 28 – 31 in packet W/ Questions

Photoreceptors & Light Control Where are these? • blind spot – the place on the retina where the optic nerve leaves the eye on its way to the brain – NO photoreceptors – cannot see anything that reaches only this part of the retina – brain uses top-down processing to to “fill in the gaps” • fovea – a tiny area in the center of the retina at which vision is at its best • contains only cones • explains difficulty of reading out of corner of eye

Step 1 - Gathering Light • Gather Light – -light reflected off object, and travels though space in waves • Waves determines hue or color • color we see depends upon light intensity & hue Wavelength – distance from one wave to next • The length of the wave gives us it’s hue (color) ROY G BIV • The longer the wave the more red, The shorter the wavelength the more violet. Amplitude – waves height determines it’s intensity (brightness).

Both Photos: Thomas Eisner The Stimulus Input: Light Energy Visible Spectrum 18

What determines the wavelength (Hue)? Violet Indigo 400 nm Short wavelengths Blue Green Yellow Orange Red 700 nm Long wavelengths 19

Path of the Light Wave Through the Eye How is the eye similar to a camera? A camera must gather light and focus it, just like an eye! • cornea – transparent membrane covering front of eye, Bends light waves inward (brings image into focus) • pupil – the opening in the center of the iris (muscle controls size of pupil), through which light passes • lens –brings image into focus – Curvature – allows eye to focus on things up close (more curved) or far away (flatter) – Ability to curve decreases with age (thus stylish reading glasses)

Path of the Light Wave Through the Eye – Cont’d • Image of object is reflected upside down on the retina (light -sensitive layer of cells in the back of the eye, converts light waves to neural impulses for processing in the brain ) It contains two types of photoreceptors …. • rods –sensitive to light, not only very useful for color vision • Found almost everywhere on the retina except the fovea • Gives ability to detect fainter spots of light on the peripheral • cones –allow for color perception https: //www. youtube. com/watch? v=Wy. Lfm 5 Hs. Hc&feature=youtu. be&app=desktop

Transduction cont’d • Retina (rods/cones) bipolar cells ganglion cells (axons = optic nerve • optic nerve – the structure at the back of the eye, made up of axons of the ganglion cells, that carries visual information for further processing

Transduction Continued • Optic nerve sends info to thalamus- area called lateral geniculate nucleus (LGN). • Then sent to cerebral cortexes. • Where the optic nerves cross is called the optic chiasm.

Visual Processing • visual information originating in the right halves of the two retinas (from the left visual field) is transmitted to the right side of the occipital lobe in cerebral cortex; left half of retinas (right visual field) to left occipital lobe

Rods versus cones. . • CLICK FOR VIDEO

Vision- Receptors in the Human Eye Cones Rods Number 6 million 120 million Location in retina Center Periphery Sensitivity in dim light Low High Color sensitive? Yes No https: //www. youtube. com/watch? v=Wy. Lfm 5 Hs. Hc&feature=youtu. be&app=desktop

Fovea Demo p. 25

Blindspot Demo p. 26

The Last Phase: In the Brain • Goes to the Visual Cortex located in the Occipital Lobe of the Cerebral Cortex. • Feature Detectors – specialized cells/neurons in the visual cortex that http: //www. youtube. com/watch? v respond to specific features ( lines, motion, =IOHayh 06 LJ 4&safety_mode=tr ue&persist_safety_mode=1&safe curves )of a stimuli (this turkey) turkey. =active *Discovered by Hubel and Weisel • Parallel Processing – brain conducts different types of analysis of info at same time. , and these feature detectors work together to build up a complete image of what we are seeing. • But what if they are damaged? http: //www. youtube. com/watch? v=I 4 cj. MV 98 e 10

The Visual Cortex: David Hubel and Torsten Wiesel (1963) • won Nobel Prize for research on feature detectors (in cats) – recorded activity of a single neuron in a cat while it looked at patterns that varied in size, shape, color , and movement – found that the visual cortex has neurons that are individually sensitive to different types of lines and angles – Noted that when deprived of certain types of visual stimulation early one, kittens lost the ability to perceive these patterns • Suggests there might be a critical period in visual development and that the brain requires stimulation it its efforts to delegate its resources to different perceptual tasks brain “learns” to perceive through experience. So what if these are damaged? http: //www. youtube. com/watch? v=I 4 cj. MV 98 e 10

Visual Information Processing Feature Detectors – neurons in the visual cortex respond to specific features – shape – angle – movement Cell’s responses Stimulus Illusory Contours So what if these are damaged? Subjective Contours http: //www. youtube. com/watch? v=I 4 cj. MV 98 e 10

Check for Understanding p. 30

Parallel Processing – simultaneous processing of several dimensions through multiple pathways (color, motion, form, depth)

Aim: How do we see color/ depth? DO NOW: 1. Take out your HW. 2. Go over Test 3. Can a one eyed man land a plane? HW: • Ear Map Handout

Pulfrich Illusion • When a dark lens placed in front the right eye the pendulum seems to take on an elliptical orbit, and appears to be revolving counterclockwise. • If the left eye is covered, the pendulum would appear to be revolving clockwisefrom-top, appearing closer as it swings toward the left and farther as it swings toward the right.

Pulfrich Illusion • Eye behind the dark lens perceives the image later than the eye behind the clear lens. • Pulfrich illusion occurs because of the time delay between your two eyes. The delay/ difference is perceives as depth. • Retinal Disparity

Depth Cues • Eleanor Gibson and her Visual Cliff Experiment. • If you are old enough to crawl, you are old enough to see depth perception. • We see depth by using two cues that researchers have put in two categories: • Monocular Cues • Binocular Cues

Binocular Cues • We need both of our eyes to use these cues. • Convergence (as an object comes closer our eyes have to come together to keep focused on the object). • Retinal Disparity (as an object comes closer to us, the differences in images between our eyes becomes greater.

Task: Work with your partner and … One person will be the pitcher and one person the catcher. • Round 1 – Pitcher throw the ball to the catcher 10 times. Both the pitcher and the catcher have BOTH eyes open. Catcher must catch with ONE HAND! Record the number of times the ball was caught. • Round 2 – Pitcher throws the ball to the catcher 10 times with BOTH eyes open, but the catcher must catch with one hand AND ONE EYE CLOSED. Record the number of times the ball was caught. **Why is one eye worse than two when catching?

Task # 2 – The Magic Hotdog Trick

Monocular Cues • You really only need one eye to use these (used in art classes to show depth). • Linear Perspective • Interposition • Relative size • Texture gradient • Shadowing • Height in Field

Find examples of the following monocular cues on your handout • Interposition • Height in Plane • Relative Size • Shadow • Linear Perspective • Texture Gradient

IDENTIFY THE MONOCULAR CUE USED….

Linear Perspective

Texture Gradient

Interposition

Relative Size Cue

Monocular Task: 1. Which monster appears larger? Which line? 2. What monocular cues to depth cause this illusion?

Color Vision Two Major Theories

Trichromatic Theory Young (1802) and Helmholtz (1850) You see colors according to their response to the wavelengths of light striking the retina---short-preferring (blue), middle-preferring (green), and long-preferring (red). Three types retinal color receptors (cones) : • Red • Blue • Green • These three types of cones can make millions of combinations of colors. • Does not explain afterimages, but DOES explain color blindness.

Are You Colorblind? Color Blindness – inability to perceive colors – lacks cones or malfunction cones Color Weakness – inability to distinguish some colors Red-green most common in men, recessive trait on X chromosome

Visual Information Processing Opponent-Process Theory- opposing retinal processes enable color vision, sensory receptors are in pairs , if one is firing the other is inhibited “ON” “OFF” red green red blue yellow blue black white black

Visual Information Processing Color Constancy Perceiving familiar objects as having consistent color, even if changing illumination alters the wavelengths reflected by the object

What is changing in each panel?

Light Characteristics 1. Wavelength (hue/color) 2. Intensity (brightness) 3. Saturation (purity) 65

Wavelength (Hue) Hue (color) is the dimension of color determined by the wavelength of the light. 66

Intensity (Brightness) Intensity Amount of energy in a wave determined by the amplitude. 67

Intensity (Brightness) 68

Purity (Saturation) Saturated 69