Just like all humans can do right now, right?
I never see any humans on the rode staring at their phone and driving like shit.
Just like all humans can do right now, right?
I never see any humans on the rode staring at their phone and driving like shit.
To the posters commenting on how amazing it is Americans are wowed by the obvious: there’s an entire electric train network called BART throughout the land surrounding this small peninsula run of Caltrain. And it’s been running since the 60s so it’s not really new to us. It’s also noisy as shit because the wheels are dumb. But it’s still fast.
You using a different kind of sumac than the rest of us? https://en.wikipedia.org/wiki/Sumac#In_food
It’s for a 3/4 cup serving which doesn’t seem all that unreasonable.
Paper lets the flour breathe, releasing moisture. The grain isn’t 100% when milled and the milling process generates significant heat (mill some grain at home with a motorized mill and see). Warmth + moisture + hermetically sealed plastic smells like a nice way to grow some fungus.
Edit: isn’t 100% dry when milled.
I get that people like to be stubborn about this but there are very real and intuitive reasons that decimals don’t make sense everywhere. Consider how intuitive telling time using “kiloseconds” and decimals might be.
The right tool needs to be used for the right job. I am a scientist. In the lab, metric is fantastic as it allows for precision recording and I don’t care about intuition.
It’s not a point of pride to use one system over another. For example, in America we use both systems in the right contexts. I am happily able to fluidly switch between what’s most appropriate for the situation. I get that context/code switching is generally difficult but I think it’s an overall value add.
If you don’t fight it and accept that imperial is designed with base 12 and not base 10, everything makes more sense. Measurements across all of imperial are to be cut into 12, 6, 4, 3, or 2.
Sometime base 12 works really nicely, especially outside of a lab, when you want to be able to have as many options for division easily as possible.
No, the analogy is more that the oscillations are themselves the particles.
The addition of energy into a system would be this hand push. The fact that the particles themselves exist means that they are oscillations in this mesh (with some energy/frequency). Interactions with other particles can add or remove energy.
Definitely these canvas metaphor are just conveniences. Also, I got it from Zee’s “Quantum Field Theory in a Nutshell” which is a standard graduate or advanced undergrad level book on QFT.
Special relativity definitely overlaps with quantum mechanics and that overlap forms the basis of the math used at collider experiments like those at the LHC. Special relativity is simple with 2 rules that let you derive all the equations: 1) no universal reference frames 2) speed of light is constant.
You’re probably thinking about general relativity which defines gravity through the curvature of space time.
If you think about quantum mechanics existing on some “canvas”, that might look like an interlocking mesh of springs (like something under a bed or cot). You could take your hand and bounces it up and down on this mesh, adding oscillations and creating standing waves in the grid. These oscillations would be different particles (electrons, protons) each with their own characteristic frequency of oscillations. If you add energy to the bed of springs, you can “pop” particles into existence. All these particles actually are are just excitations of the mesh/canvas. As of yet, there’s been no way to define or find the gravity particle on this canvas, so right now the canvas of space time and the canvas of quantum mechanics are two distinct “things”.
Cheque? lol don’t give yourself away too hard comrade.
How long ago? ROOT (and other frameworks like GEANT) using C++ has been the standard for over 15 years, but probably longer. I think my advisor was of the last generation that had to write in Fortran.
There’s a remarkable difference in the quality of apps delivered from major tech companies using US developers and apps from contracted employees in places like Eastern Europe. You get what you pay for.
Having said that, I’m sure that there are good developers everywhere in the world. I’m not sure that excellence in the field is as widely rewarded as it is in the US, so why should the quality be high?
For software, if you’re used to big tech wages, you’re not taking less than $180k base. RSUs are probably somewhere like $400k initial grant, anywhere from 25k-100k yearly refresher. US engineers (good ones) are the furthest from cheap.
Bipping is the act of stealing from cars, often through the use of “splashing” (breaking the car windows).
I swear people here are either too young or didn’t use the internet 8 years ago. All of this stuff was super common to search and get the first result back as the right answer.
You’re imagining a future where screen resolution doesn’t improve and lenses can’t solve these issues? Are people really this short sighted?
You could easily create a package that couples the authenticated device with a screen showing the faked images and bring that around. If there is a market for inauthentic images that appear authentic, people will easily bypass this technology.
Just take a picture of your manipulated picture/video from the Sony phone. This does not guarantee anything of value.
I found this repo interesting just for the sake of centralizing a lot of useful info around VHS. Even if you don’t follow this path, the knowledge might help: https://github.com/oyvindln/vhs-decode
But if the average is better, then we’re will clearly win by using it. I’m not following the logic of tracking the worst case scenarios as opposed to the average.