why are we able to see in a dark room? after our eyes adjust to the darkness via rods/cones you can still see stuff like the dresser or a pair of shoes on the ground. Rods are the photoreceptors in your eyes that are used for night vision ... while cones respond to hue/wavelength, rods react to intensity. Cones offer you acuity as well; something the rods do not provide. So the effects are two-fold at least: you lose the ability to discern color/"hue" and your visual acuity plummets.....
i'm guessing there's still some minute source of visible band radiation in the area. this is different from being in pitch black darkness in which no light is present, which, in turn, is different from true darkness where no light in the visible spectrum is present.....
i'm guessing: a casket, a forest with the sky covered by thick trees otherwise starlight may be noticeable unless said forest is located in a particular location which prevents clear weather(etc), or deep within the ocean where light apparently has a tough time penetrating.
in a dark room, while objects can be made out, if one had infrared thermometers then more detail of the objects could be made out (any other implications?)... improved detail insofar as there exist temperature gradients in said blackbody apparently room temperature objects emit radiation in the infrared. Read: blackbody radiation. however, it is still possible to make out the objects due to rods and cones. Not possible for cones to function in low light. i would have to guess that there is still some source of visible light available, perhaps the light is on in the kitchen or some light is getting in through somewhere.
if the sun emits mostly visible light, what is the process of seeing stuff? the waves or photons hit an object, bounce off/reflect/get absorbed & emitted which then enter our eyes due to the sheer amount and we have this ability to process it and make out the overall idea of the object that is reflecting the radiation into our eyes? any discussion might be helpful, and appreciated.
Haven't done a color coded reply in a while so I hope you liked it.
I expect that scorpiomover will join this thread at some point and will provide four or five long deep paragraphs that answer all of your questions, however, I just want to point out a few things to steer you in the right direction; "big picture" explanations are not my forte but I'll give it a shot for the sake of self-improvement.
Key concepts for further study: retinotopic organization, thalamus, "dorsal stream", "ventral stream"
Perception, in general, follows a fairly linear process.
1. External stimulus (light) enters the body through the pupil and is focused (
projected) on the retina by the lens.
2. Sensory receptors (rods and cones) are
excited by the stimulus
3. A nerve impulse is generated through the action of the receptors (advanced topic - university level - very easy to forget over time (
(i.e. further reading)))
4. The signals enter the brain through the thalamus (primary processing center) - bilaterally located deep in the middle of the brain, the thalamus receives input from the sensory system (i.e. via the optic or other cranial nerves, such as auditory), and begins to
organize the raw data into a meaningful representation.
The thalamus is a collection of
nuclei (typical usage of the word), which has nuclei for nearly every sensory system. The nucleus we are specifically concerned with is the
lateral geniculate nucleus (LGN).
5. As the thalamus generates meaningful clusters of data it sends them to the primary visual cortex (VI -
striate cortex) where the first levels of visual processing occur (initially,
contrast between two areas of the visual field).
*I am being vague with the true functional role of the thalamus for the sake of simplicity. When I say "meaningful representation" and "clusters of data" I really mean to say that the LGN is basically bombarded with retinal information and it organizes and sorts different components of the visual picture (some data from
rods, some data from
cones), then sends it off to their respective regions of the brain (or
pathways if you will) ... it's all sorted here, before it reaches the cortex.
This is like, first degree integration... ordering like terms , or whatever other form of simplification you prefer
Now is when any semblance of linearity goes flying out the window .....
6a. The striate cortex also sends a fair amount of visual information
backto the thalamus so it can be relayed again to other areas of the perception system (namely the superior colliculus, which mediates the reflexive "turn and look response") ((this is actually a two way street))
Generally (perception = integration) and (sensation = differentiation) if you want to take a more conceptual stance.
The cortex is basically layer upon layer of cell bodies, and each layer sort of has a very specific and complicated "job" when it comes to processing the visual field. Effectively, though, just remember it simply fires an action potential when its time has come, whatever its purpose may be. Quite often it is when its (
el neuron) respective visual field (see: retinotopic organization of cortex) is stimulated.
^This "layers of cell bodies" concept is crucial to the next step, in that we are setting up two distinct "pathways" of information to be processed through the "higher" regions of the cortex (i.e. further integrated into a whole) (((read: gestaltism)))
6b. Pathway 1 - dorsal stream "where and how" pathway
6c. Pathway 2 - ventral stream "what" pathway
[bimgx=250]http://www.rrnursingschool.info/nervous-system/images/8160_269_713-dorsal-ventral-visual-stream.jpg[/bimgx]
