A truck tire sheds its retread and the pieces fly all over the road. Every car driving past randomly hits the pieces and they randomly fly about. But the end result is not random, the pieces end up off the driving surface. It may be that the pieces fall in random places and the time it takes to get off the road is random, but the pieces end up predictably off the road every time. The cars hitting the tire shreds were not random.
Those tire bits can be big enough to cause traffic accidents in following cars. Engineers at tire making companies have to consider the possibility that one of their exploding tires might cause death. There's a tradeoff involved between safety, cost, and convenience. Somewhere along the line, someone has to make a decision about what to do. When they make that decision, they use random numbers in their calculations.
Yes, all those pieces end up off the road. If that's what you are wondering about, then you can say that the result is not random. However, some people care, with good reason, about how and why they end up off the road. In order to model the process, you have to use randomness.
That is not a random process.
You are using a phrase, "random process", that has a very specific meaning, and your example is indeed a random process. When engineers study random processes, the most common applications are control systems and communication lines. Everyone who designed your cable TV system had to study random processes. That doesn't mean that your TV is showing random images, although sometimes it seems that way.
Engineers care, not just about the final destination, but about the path. They aren't wrong to do so. For them, that tire shredding phenomenon is a random process. Similarly, evolutionary biologists may very well care about the path, not just the destination. To model evolution at a numerical level, you must use random processes.
On the other hand, to describe what happened at a coarse level, or to describe trends (the "whole"), you don't need to use random processes. It all depends on what aspect you are studying.
Not a thing. There is one small part of the process of evolution that is random. I don't believe a single person in this thread disagrees with that statement.
There's at least one, and I suspect more. One small part is the mutations. Those are random. Without it evolution wouldn't happen. Another small part is the final outcome. That's random. Another small part is the actual events which, when aggregated, become known as "natural selection". Those are random (in the mathematical sense). The only thing that isn't random is the pattern. So which is more important? I don't think either, myself.
So I repeat my question, reproduction is a part of evolution. Is it accurate to describe evolution as a birthing process?
No.
Is it even accurate to describe evolution as a process of reproduction?
No.
Would anyone think you were describing evolution, or would they recognize you were describing some part of the process, not the process?
No.
Of course, "birthing process" and "random process" are very different sorts of phrases, so I'm not sure how the analogy really applies.
How random is that yersinia pestis' acquisition of specific antibiotic resistance genes against antibiotics that other organisms have been subjected to but the yersinia organism has not?
Are you talking about an individual organism, or the species as a whole. On an individual level, very random. However, the large numbers involve mean that somewhere, some individual will likely get the resistant genes, and so it is highly likely that the species as a whole will get the resistance.
What aspect are you interested in? Are you interested in whether or not it develops the resistance, or the mechanism by which it develops the resistance. If you are interested in the latter, the mathematics of probability will be very useful to you in your studies.
How is the yersinia developing resistance to antibiotics which have never actually exerted selection pressures on the organisms? Certainly not through random processes.
Again, the phrase "random process" has a very specific meaning, and the development of antibiotic resistance can be modelled as such.
