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The Parker Solar Probe will make its closest approach yet to the Sun

(arstechnica.com)
164 points pseudolus | 22 comments | 20 Dec 24 11:23 UTC | HN request time: 0.001s | source | bottom
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kfogel ◴[20 Dec 24 21:27 UTC] No.42475215[source]
Most of the comments so far are about the temperature and the closeness to the sun, and, hey, I get it: those are both amazing to think about. But to me even more amazing is... 0.16% of the speed of light?? Yikes.
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1. verzali ◴[20 Dec 24 21:37 UTC] No.42475305[source]
Pretty sure it's 0.064%, not sure why the article got it wrong, still impressive though
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2. caseyohara ◴[20 Dec 24 22:39 UTC] No.42475809[source]
Still. ~200,000 m/s (= ~430,000 mph) is unfathomably fast.
replies(2): >>42477069 #>>42477229 #
3. jebarker ◴[21 Dec 24 02:30 UTC] No.42477069[source]
It is, although I was still a little surprised it's on the order of a minute to go NYC to Tokyo at that speed. My intuition was it would be much less time.
replies(2): >>42477266 #>>42478325 #
4. Ankaios ◴[21 Dec 24 03:04 UTC] No.42477229[source]
~200,000 m/s is unfathomably fast.

It's about 110,000 fathoms per second.

replies(1): >>42477683 #
5. tehjoker ◴[21 Dec 24 03:12 UTC] No.42477266{3}[source]
Light loops around the earth ~7.75x a second iirc so a few orders of magnitude less makes sense
6. fy20 ◴[21 Dec 24 05:12 UTC] No.42477683{3}[source]
Or if you prefer leagues, at that speed it would still take 9 minutes to reach the depth in Jules Verne's book.
replies(1): >>42477899 #
7. mwcremer ◴[21 Dec 24 06:33 UTC] No.42477899{4}[source]
The title refers to the distance the _Nautilus_ traveled while submerged, not the depth it reached.
replies(2): >>42479011 #>>42479418 #
8. sandworm101 ◴[21 Dec 24 08:50 UTC] No.42478325{3}[source]
Light is fast, but it isn't imperceptible. The original experiments to measure it in a lab involved spinning rigs and mirrors between hills. When dealing with objects the size of continents, such as phone or other communication systems, the delays are well within our abilities to detect.
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9. ◴[21 Dec 24 11:23 UTC] No.42479011{5}[source]
10. MereInterest ◴[21 Dec 24 13:00 UTC] No.42479418{5}[source]
Until I realized this, the title was quite confusing. If “20,000 leagues” were referring to depth, it would be enough to go all the way through the Earth, exit the other side, and then make it a quarter of the way to the moon.
replies(1): >>42479923 #
11. Loughla ◴[21 Dec 24 14:35 UTC] No.42479923{6}[source]
Yeah he really needed a comma.

20,000 Leagues, Under the Sea

I think it reads cleaner.

12. gosub100 ◴[21 Dec 24 16:57 UTC] No.42480715{4}[source]
terrestrial phone / internet carried by undersea cables are gated by the relays more so than c. the ping time from US to Australia (one way) is about 115 ms (rounding down, using most optimistic data.

Light can travel over 34,000km in that time. The great arc distance from LA to Sydney is just over 12,000km. In all likelihood the fiber line connecting them doesn't follow that arc, but it shouldn't be too far out of limits. So about 2/3 of the latency is caused by relays and switching equipment.

it gets even worse for satellite, because (until starlink) communications satellites are in geosynchronous orbit, 35,000km above the equator. so talking on one means a 70km round trip, which causes its path to take over 5x more distance than the linear distance (across the surface) between those 2 cities.

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13. andrehacker ◴[21 Dec 24 17:27 UTC] No.42480923{5}[source]
>> The great arc distance from LA to Sydney is just over 12km.

12,000km ?

replies(1): >>42480943 #
14. jebarker ◴[21 Dec 24 17:29 UTC] No.42480939{4}[source]
Yeah, it always sticks in my mind that the time it takes for light to reach the top of the Eiffel tower from the ground is measured in nanoseconds. Maybe that came from a Grace Hopper talk?
replies(1): >>42481368 #
15. gosub100 ◴[21 Dec 24 17:30 UTC] No.42480943{6}[source]
fixed, thank you
16. irrational ◴[21 Dec 24 17:52 UTC] No.42481066{4}[source]
Right now I’m reading the Expeditionary Force series and one thing the author drives home is how incredibly slow the speed of light is.
replies(1): >>42481400 #
17. Denvercoder9 ◴[21 Dec 24 18:43 UTC] No.42481368{5}[source]
Microseconds even! Light travels about 0.3 meter in a nanosecond, and the Eiffel tower has a height of ~300 meter, so it takes about a microsecond for light to get from the ground to the top.
18. Denvercoder9 ◴[21 Dec 24 18:48 UTC] No.42481398{5}[source]
> So about 2/3 of the latency is caused by relays and switching equipment.

Not really; the speed of light in fiber optic cable is only about two-thirds of that in a vacuum. That means it takes light about ~60ms to travel the 12,000km great arc distance.

replies(1): >>42481408 #
19. pishpash ◴[21 Dec 24 18:48 UTC] No.42481400{5}[source]
The speed of light is the speed of causality, so obviously it can't be too fast or everything will be in instantaneous causal contact. It's not strange that biological creatures find that things over distances that "feel" distant actually take light some perceptible "time" to reach.
20. gosub100 ◴[21 Dec 24 18:49 UTC] No.42481408{6}[source]
thats a great point, I failed to consider c in the propagation medium. however, OP didn't specify that either, he just insinuated that we can perceive propagation delays by c. we are both wrong (in his specific case about telecom delays, we have absolutely contrived experiments to detect it)
21. belter ◴[21 Dec 24 19:07 UTC] No.42481519[source]
Correct. About 18 milliseconds of time dilation per day assuming 690,000 km/h - 430,000 mph.
22. sandworm101 ◴[22 Dec 24 01:26 UTC] No.42483749{5}[source]
>> it gets even worse for satellite, because (until starlink) communications satellites are in geosynchronous orbit

No. There were and are other communication satellites in lower orbits. SpaceX did not invent the concept of low-orbit communications satellites. The first satellites of the 90+ Iridium constellation were launched in the late 90s. That system is still online in low orbit today. Before that there were various military/state-owned satellites. The Soviet Union and Russia were big on providing coms to areas where the geo-stationary relays could not, specifically the north, as far back as the 60s. See the Molnya program.

https://en.wikipedia.org/wiki/Molniya_(satellite)

https://en.wikipedia.org/wiki/Iridium_satellite_constellatio...