What the papers seems to conclude it that there exists what they call "adverse interactions between
motivational signals and diverse neural functions, including cognition and perception", one is still curious about an logical explanation for this? From the perspective of performance and rewards, this seems to be as they put in the review "the brain gets it wrong". But most of the time, the brain has evolved for a long time, so what is the "reason" for why brain "gets it wrong"?
I think they phrased this poorly. Evolution has wired us for survival and for the most part that means being very cautious. āShould I run across that area to the bush laden with fruit with that sabre tooth tiger just over there?ā Empty stomach says, āYou can do it!ā, legs and cardio system say, āYes you can!ā, brain says, āHang on, hang on, letās just wait a few hours until Sabrey-baby has gone away. We wonāt starve over that time. Cognitive areas of the brain are in conflict with the autonomic system and do their best to prevent a dangerous situation inhibiting areas of the brain that will all them to take the body into that risky situation. But completing the task is probably quite feasibleā¦.the cognition has underestimate our abilities (gets it wrong).
The first thing that comes to my mind - if you view the brain as an information processing agent in a competitive environment - is to speculate that it has to do with resource management, or limted information capacity of processing.
Nicely put!
Perhaps the same "capacity" of "processing hardware" (from neural networks) is used for many things (multitasking).
We are not capable of multitasking, only rapidly switching between the currently most salient task. This switching is performed by the basal ganglia. Some peopleās basal ganglia are faster at switching than others. Most of us can switch between 3-4 tasks. Fighter pilots and astronauts can switch between up to ten and their selection tests have this ability built into them. I can switch between 37 tasks
A lifeform must maintain many importan processes in parallell. So perhaps when a HIGH reward is presented, the brain sees is as an opportunity we can't afford to miss, and gives disproportional priority to processing the benefits of the reward itself, at the expensiv of focusing on execution.
For grabbing a fistful of grapes, with a snake close to the bunch, perhaps, but for the multi-stage task of defusing a complex bomb, where precision is a necessity, this might be an issue, there may be neural conflict and choking.
The paper found that motor activity was not affected, but was mistunded. Could it be like when error rates and thus response rates decrease on a network when the traffice gets too high?
The motor control system has many levels of processing in a hierarchy. Very simply, the motor cortex is at the top acting like an army Major General. The basal ganglia (BG) and the cerebellum are below it like brigadier generals, below that are the spinal cord circuits. Say youāre walking along an icy pavement and slip on a patch. The BG and cerebellum notice a mismatch between intention (from descending command) whatās actually happening to your body (feet slipping and leg up in the air) information from various peripheral receptors. The BG and cerebellum report back to the motor cortex saying it needs to quickly send down error correction commands to the muscles to correct the intention/execution mismatch which it does. The BG and cerebellum check the orders are reasonable for the environmental situation (they error correction signals would be different if you were on an icy tightrope!) and let them pass down to make you stagger around, flail your arms around and regain your balance again! The cerebellum is a bit different to the BG in that it can calculate an error correction signal and send it down to the muscles quicker that going through the whole hierarchy. The BG does have that ability. All of this is incumbent upon the complexity of the situation since neural processing power is limited.
So the "brain gets it wrong" needs qualification IMO.
I agree. It was poor phrasing, but a good headline!
I have deep respect for the evolved brain, so maybe it seems to get it wrong,
The problem with the brainās evolution is that newer (better adapted) structures have had to be built on older structure. Itās like improving a carās engine without removing the original designs: like a hybrid car still with a redundant starting crankā¦.redundant until the battery goes flatā¦
from the perspective of an artifical test, but maybe what that brain does, is the best it can do.
You often hear people say evolution is āsurvival of the fittestā. Thatās incorrect and misleading. They should say, āsurvival of the best adapted [to the current environment]ā. A shark is the best adapted to oceanic life, but place it in a shade woodland area and itād soon die! Put a kangaroo in a rainforest and it too wouldnāt last very long. Our brains are very well adapted to low speeds, our bodies to moderate temperatures and pressure etcā¦.our environment. Put it at relativistic speeds and it simply will not copeā¦it hasnāt evolved to.
IF this is the case, it seems questionable to say that the "brain gets it wrong"?
What do you think?
The situations where the brain chokes are highly artificial. Examinations and elite sporting events. Our brains werenāt evolved to handle those situationsā¦well competition of sorts but not with spectators TV cameras etc. Some brains are better than others in these situation and if there was a survival advantage to those situations, theyād be the ābest adaptedā and pass on those traits to the next generation!
Sorry for the rambling response. I hope it helps?
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