The typical HN person works as a software engineer, and the typical software company makes money, either directly or indirectly, via targeted ads. And these ads are served via a surveillance infrastructure that would not be out of place in a dystopian science fiction novel.
Even the companies that don't make money from ads have no qualms just letting Google or Facebook collect data about their website visitors.
This is why it's important to build a diet with grains and beans. They are cheap and last for months/years at home if stored properly. So you can easily have enough stored at home to eat for at least a few weeks.
It's important to note that the Salling Group is privately owned with only a few owners [1]. It's easier for such companies to do such things than a publicly owned one.
Public companies do this sort of thing too, or at least they used to. It's typically grouped under 'Corporate Social Responsibility'. They aren't doing it out of pure altruism:
From https://benevity.com/resources/corporate-social-responsibili...
"CSR increases customer retention and loyalty: Research shows that 87% of Americans are more likely to buy a product from a company that they can align their values with, and over half of all consumers are willing to pay extra for a product if they’re buying from a company with a sturdy CSR strategy."
Thanks for the perspective. I think it's difficult for small cities like Pontevedra to create high quality jobs. There are not enough people to support rich doctors, lawyers, accountants and such. Factories can be established, but most people employed in a factory won't have a "high-quality" job. What other type of high-quality job could the city create?
[1] population ~ 80k, but working population ~ 50k.
Your perspective is really skewed here. 80k is easily enough to support multiple hospitals, specialist doctors, many dentists, and several multi hundred employee specialized companies.
I live in a city like this. We have muni employees, a hospital, some startups, plenty of non-tech jobs. There are doctors, lawyers, accountants, tradespeople, restaurants.. 80k is a LOT of people.
Side note: an hospital in Spain can be a relatively building with a few specialists, perhaps 20 people working here counting the staff. On many other countries an hospital is a huge building with dozens of specialists. The small places are "medical/care center". For sure there’s specialized jobs here too.
Most Physics undergraduate programs have a course on Modern Physics, which is often taught in the way you are asking for. Though only up to the origins of quantum mechanics. This textbook, for example does this [1].
The problem is that after the basics of QM, there were literally hundreds of papers by dozens of important scientists developing the subsequent theory. And you can no longer teach the subject in a linear historical fashion.
Do you have proof that demonstrates that FB's algorithm is more harmful than upvotes on HN or Reddit? Not that it's harmful compared to a world before FB, that it's more harmful than an upvote based algorithm.
The question is why "so many real-world systems are governed by differential equations" and "so many real-world systems involve periodic motion".
Well, stable systems are can either be stationary or oscillatory. If the world didn't contain so many stable systems, or equivalently if the laws of physics didn't allow so, then likely life would not have existed. All life is complex chemical structures, and they require stability to function. Ergo, by this anthropic argument there must be many oscillatory systems.
Differential equations aren't limited to describing stable systems, though, and there are chaotic systems that are also in some sense stable.
Ordinary differential equations can describe any system with a finite number of state variables that change continuously (as opposed to instantaneously jumping from one state to another without going through states in between) and as a function of the system's current state (as opposed to nondeterministically or under the influence of the past or future or some kind of supernatural entity).
Partial differential equations extend this to systems with infinite numbers of variables as long as the variables are organized in the form of continuous "fields" whose behavior is locally determined in a certain sense—things like the temperature that Fourier was investigating, which has an infinite number of different values along the length of an iron rod, or density, or pressure, or voltage.
It turns out that a pretty large fraction of the phenomena we experience do behave this way. It might be tempting to claim that it's obvious that the universe works this way, but that's only because you've grown up with the idea and never seriously questioned it. Consider that it isn't obvious to anyone who believes in an afterlife, or to Stephen Wolfram (who thinks continuity may be an illusion), or to anyone who bets on the lottery or believes in astrology.
But it is at least an excellent approximation that covers all phenomena that can be predicted by classical physics and most of quantum mechanics as well.
As a result, the Fourier and Laplace transforms are extremely broadly applicable, at least with respect to the physical world. In an engineering curriculum, the class that focuses most intensively on these applications is usually given the grandiose title "Signals and Systems".
One amazing application of spectral theory I always harp on when this topic comes up is Chebfun[1]. Trefethen's Spectral Methods in Matlab is also wonderful.
That first question is a tautology. It’s like asking “Why is a screwdriver so perfect for turning screws?”
We have discovered a method (calculus) to mathematcally describe continuous functions of various sorts and within calculus there is a particular toolbox (differential and partial differential equations) we have built to mathematically describe systems that are changing by describing that change.
The fact that systems which change are well-described by the thing we have made to describe systems which change shouldn’t be at all surprising. We have been working on this since the 18th century and Euler and many other of the smartest humans ever devoted considerable effort to making it this good.
When you look at things like the chaotic behaviour of a double pendulum, you see how the real world is extremely difficult to capture precisely and as good as our system is, it still has shortcomings even in very simple cases.
What ought to be surprising is that the "thing" itself doesn't change.
A learning that describes chaos well enough may not want to be associated with "calculus", or even "math" (ask a friendly reverse mathematician about that)
Somewhat tangentially, if Ptolemy I had responded (to Euclid) with anything less specific ---but much more personal--- than "check your postulate", we wouldn't have had to wait one millennium.
(Fermat did the best he could given margin & ego, so that took only a century or so (for that country to come up with a workable strategy))
Less tangentially, I'd generalize Quigley by mentioning that groups of hominids stymie themselves with a kind of emergent narcissism. After all, heuristics,rules and even values informed by experience & intuition are a sort of arrogance. "Tautology" should be outlawed in favour of "Narcissism" as a prosocial gaslighting term :)
> The question is why "so many real-world systems are governed by differential equations" and "so many real-world systems involve periodic motion".
>
> Well, stable systems are can either be stationary or oscillatory. If the world didn't contain so many stable systems, or equivalently if the laws of physics didn't allow so, then likely life would not have existed. All life is complex chemical structures, and they require stability to function. Ergo, by this anthropic argument there must be many oscillatory systems.
I would say that the it's very difficult to imagine a world that would not be governed by differential equations. So it's not just that life wouldn't exist it's that there wouldn't be anything like the laws of physics.
As a side note chaotic systems are often better analysed in the FT domain, so even in a world of chaotic systems (and there are many in our world, and I'd argue that if there wasn't life would not exist either) the FT remains a powerful tool
> Well, stable systems are can either be stationary or oscillatory.
In practice this is probably true, but I can see another possibility. The system could follow a trajectory that bounces around endlessly in some box without ever repeating or escaping the box.
You can treat that, and scientist often do treat it, as a stationary system with some error bounds.
For example, the concept of homeostasis in biology is like this. Lots of things are happening inside the living body, but it's still effectively at a functional equilibrium.
Similarly, lots of dynamic things are happening inside the Sun (or any star), but from the perspective of Earth, it is more or less stationary, because the behavior of the sun won't escape some bounds for billions of years.
If this box was of a bounded size then that trajectory would have interesting property - there are chunks of time you can edit out such that what remains will look as if they are converging on a point.
> Under capitalism necessities become luxuries, while luxuries become false necessities. Umair Haque
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