Deck 5: Vision

A) photoreceptors; horizontal cells
B) amacrine cells; horizontal cells
C) photoreceptors; ganglion cells
D) amacrine cells; photoreceptors

A) retina cells
B) bipolar cells
C) ganglion cells
D) spiny cells

A) neurons in the ear send impulses that are interpreted as sound.
B) neurons in the eye detect light energy.
C) chemicals are the specific energy detected by receptors in the nose and tongue.
D) although found in different places, the same kind of receptors on neurons are able to detect light and sound.

A) retina
B) cornea
C) pupil
D) macula

A) The optic nerve
B) The fovea
C) An area containing mostly rods
D) The cornea

A) Rods and cones
B) Bipolar cells
C) Horizontal cells
D) Ganglion cells

A) have no discernible fovea
B) have a greater density of receptors than do humans on the top half of the retina
C) have a greater density of receptors than do humans on the bottom half of the retina
D) are virtually indistinguishable from the retinas of humans

A) Retinol; photopigments
B) Opsins; retinol
C) Photopigments; opsins
D) Opsins; photopigments

A) short-wavelength cones
B) rods
C) lens
D) long-wavelength cones

A) photo-optics
B) photopigments
C) opsins
D) kestrels

A) It is very sensitive to detail.
B) It is easier to recognize single objects in the periphery that are not surrounded by other objects.
C) It is not very sensitive to light.
D) It is most sensitive to color, which helps to differentiate multiple objects clearly.

A) cones; sensitive to detail
B) rods; sensitive to bright light
C) cones; sensitive to movement
D) rods; sensitive to colors

A) It is closest to the pupil.
B) It surrounds the optic nerve.
C) It has tightly packed receptors.
D) It contains many blood vessels for supplying energy.

A) On the right half.
B) On the left half.
C) It depends on the brightness of the light.
D) It depends on the color of the light.

A) Phototransmitters
B) Photosins
C) Photopigments
D) Photoions

A) opsins
B) unstable proteins
C) all-trans-retinal
D) sodium

A) better peripheral vision
B) larger blind spots
C) a greater rod to cone ratio
D) a greater cone to rod ratio

A) Receptors
B) geniculate cells
C) amacrine cells
D) optic nerves

A) Receptor cells, ganglion cells, bipolar cells
B) Ganglion cells, bipolar cells, receptor cells
C) Receptor cells, bipolar cells, ganglion cells
D) Bipolar cells, receptor cells, ganglion cells

A) cones; responsive to movement
B) rods; sensitive to dim light
C) cones; likely to be bleached by sunlight
D) rods; useful for seeing fine details

A) optic nerve; saccade
B) optic nerve; blind spot
C) fovea; saccade
D) optic chiasm; blind spot

A) straight to the brain
B) immediately to ganglion cells within the retina
C) to bipolar cells within the retina
D) to the periphery of the retina first, ganglion cells next, and bipolar cells last

A) It has the greatest perception of detail.
B) It surrounds the point of exit of the optic nerve.
C) It falls in the shadow cast by the pupil.
D) It has more rods than cones.

A) the periphery; the fovea
B) red; blue
C) vertebrates; invertebrates
D) reading text; reading road signs

A) Retinex theory
B) Opponent-process theory
C) Trichromatic theory
D) Kodak theory

A) Cones only
B) Rods only
C) Both rods and cones
D) Horizontal and amacrine cells

A) velocity of the action potential
B) absolute activity of a single cone
C) difference between cone and rod activity
D) relative activity of short, medium, and long wavelengths

A) V1; occipital lobe
B) V1; thalamus
C) lateral geniculate nucleus; thalamus
D) medial geniculate nucleus; occipital lobe

A) CRT
B) opponent process
C) retinex
D) trichromatic

A) Receptors in the periphery are closer to the pupil.
B) The fovea is closer to the retina's blind spot than peripheral receptors.
C) More receptors in the periphery than in the fovea funnel input to each ganglion cell.
D) Ganglion cells in the periphery transmit their information to a larger brain area.

A) Young-Helmholtz theory
B) Trichromatic theory
C) Opponent-process theory
D) Color-constancy theory

A) Trichromatic theory
B) Retinex theory
C) Opponent-process theory
D) Kodak theory

A) the relative activity of three kinds of cones
B) contrasting the activity in one area of the visual field with that of the others
C) a red versus green system and a yellow vs. blue system
D) detecting the velocity of action potentials from the eye

A) blue; yellow
B) green; blue
C) red; green
D) red; blue

A) She must be female because having four kinds of cones requires two X chromosomes.
B) She has two forms of the short-wavelength cone.
C) She has two forms of the long-wavelength cone.
D) She is better at making distinctions between one color and another compared to someone with three cones.

A) optic chiasm
B) lateral geniculate nucleus
C) hypothalamus
D) cerebral cortex

A) each ganglion cell excited by many receptors
B) ganglion cells respond poorly to color vision
C) ganglion cells respond well to dim light
D) each ganglion cell is excited by a single cone

A) trichromatic
B) opponent-process
C) retinex
D) constancy

A) poor eyesight
B) malformation of area V4 in the brain
C) complete absence of one of the types of cones
D) long- and medium-wavelength cones making the same photopigment

A) Horizontal
B) Amacrine
C) Bipolar
D) Ganglion

A) perceive all wavelengths as the same color
B) see color, even in very faint light
C) differentiate among many colors and hues
D) recognize the color of an object despite changes in lighting

A) there are only three rods and three cones in each eye
B) there are only three colors of light in the world
C) rods are important for perception of light colors
D) our perception of color depends on the relative activity of three types of cones

A) A different receptor for each color
B) Three kinds of cones
C) A single receptor that produces different responses for each color
D) The combined influences of rods and cones

A) opponent process; volley
B) volley; trichromatic
C) opponent process; trichromatic
D) trichromatic; opponent process

A) Receptive fields
B) Lateral inhibition
C) Retinal disparity
D) The direction in which the light shines

A) point at which the optic nerve exits the retina
B) axon hillock
C) point in space from which light strikes the receptor
D) point where light shines on, and excites, the visual cortex

A) an illusion created in the retina called lateral inhibition
B) activation of V1 by the cones
C) activating his rods and cones simultaneously
D) enhancing his ability to see red versus green

A) magnocellular neurons in the periphery
B) parvocellular neurons tightly packed in the periphery
C) no cones in the periphery
D) the strength of the eye muscles

A) lateral geniculate and cerebral cortex
B) superior colliculus and cerebral cortex
C) lateral geniculate and superior colliculus
D) prefrontal cortex and occipital lobe

A) to the lateral geniculate nucleus
B) to area V1
C) to area V2
D) back to the retina

A) the LGN
B) the retina
C) V2
D) V1

A) lateral geniculate nucleus
B) striate cortex
C) area V2
D) parvocellular area

A) right eye
B) left eye
C) peripheral vision of both eyes
D) left visual field

A) cerebral cortex
B) superior colliculus
C) inferior colliculus
D) thalamus

A) magnocellular neurons
B) rods
C) bipolar cells that receive input from cones
D) the periphery of the retina

A) LGN; occipital lobe
B) V1; occipital
C) V1; parietal
D) LGN; parietal

A) rods and cones; ganglion cells
B) rods and cones; bipolar cells
C) bipolar cells; ganglion cells
D) cones; rods

A) retina
B) primary visual cortex
C) thalamus
D) hypothalamus

A) parvocellular
B) magnocellular
C) koniocellular
D) kodacellular

A) Horizontal cells
B) Ganglion cells
C) Bipolar cells
D) Glial cells

A) thalamus; cortex
B) thalamus; inferior geniculate
C) inferior colliculus; thalamus
D) thalamus; lateral colliculus

A) Lateral inhibition
B) Movement perception
C) Dark adaptation
D) Size constancy

A) stimulus field
B) convergence field
C) receptive field
D) bipolar field

A) stimulus field
B) convergence field
C) receptive field
D) bipolar area