Why?
The overgenralisation is in the statment "opposite of random". I would accept "Opposite of the frequently used definition of random as 'directionless' "... even though it is ugly. "Natural Selection has direction, but no intelligent guidence".
I believe you are an engineer, so what problem do you the statement that a random system can have different outcomes for identical inputs, whilst a nonrandom system can't.
Hardly, I am a computer aide, with a psych degree and social work as a former profession.
Sorry, I must have been confusing you for someone with a similar name/location or posting style
In other words a nonrandom output is predetermined, whilst a nonrandom output isn't.
Now that is also a statement I don't agree with, you mean a closed system with known inputs and responses to inputs?
Schrödinger's Cat could be a closed system that is random (if the radioactive source is placed in the box next to the cat.
If you don't like cruelty to imaginary cats, you could change the response of the detector to maybe multiply an input by a factor that depended on the number of radiation counts in the preceding five seconds, or something akin to that. The external inputs will be known , and even how it responds to particular random events, but it will still produce a random output, because it has its own modification of the inputs according to some random number.
Many statistical techniques are often based on assuming not that something is *actually* random, on other confounding factors that are too complex to model.
In such cases "randomness" might be illusory, but that is not the situation in evolution.
For example, a collection of random mutations in a flu virus suddenly can make it far more lethal, so these few mutations can exert a large evolutionary pressure on birds.
A different set of mutations, and you get a different set of evolutionary pressures exerted on the host population. Just because we can't *see* proteins generated by the immune system doesn't make this evolution any less important than running ability for gazelles, for example.
It is the statement "Opposite of random" that I object to.
Now that i can understand.
Furthermore, it means that if you learn that Natural Selection is nonrandom, then if you want to study population genetics and its interaction with evolution, you will have to unlearn this "fact".
Evolution can be simply
approximated as nonrandom if you are considering sufficiently large populations in a stable environment and the environment remains stable for sufficient time. This is the easiest situation to understand, and is probably what is often implicitly assumed in discussions about how evolution works in theory. This is not what happens in real environments though. Not even in simple environments like flasks of
e-coli with no other bacteria present.
