Right, yeah, if the whole system is moving in the direction of the light being sent, it would take longer to get there, while the mirrored light would be faster, ultimately zeroing out until its back at the origin.

Sometimes, I feel like we need more blind physicists. Those wouldn’t be horribly confused when they cannot detect things along the way.

Somewhat yes. There are no unmoving objects in space, but recently scientists have measured redshift differences from distant stars to calculate very accurately their distance and how it evolves over time. This enabled them to detect gravity waves at a galactic scale, effectively turning the entire galaxy in a gravity telescope.

relative to all of space where the speed of light is constant? Make 3 of those on x, y, and z axes, and don’t you have an absolute vector of movement in our entire spatial universe?

You’re looking for an absolute standard vector, to measure absolute velocities?

Yes, I think you can make one. It’s not even hard. But how can you tell wether you are moving, or wether it is moving?

Imagine all the possible ways this vector can be in, and move through space. For all of those, you measure the same speed of light. But for each of those, you measure a different wavelength, based on it’s relative speed (and due to the universe expanding, distance) to you.

Now you can tell your relative distance and speed to any of these vectors. Like we do with other astronomical objects.

If you want to get rid of relativeness, and achieve absoluteness, you have to subjectively define which reference frame is your rest frame.

the change in energy is achived by a modulation of the wave?

Yes. Since speed is constant, all you can change is wavelength/frequency. If you try to add speed, you instead add energy, which increases frequency or shortens wavelength.

E = hc / λ

where

• E is photon energy
• λ is the photon’s wavelength
• c is the speed of light in vacuum
• h is the Planck constant

So is the speed of light constant because light is a particle and a wave?

Here, the ground is becoming shaky for me. You’re asking a good question; why. Maybe all we can find out is how. From what I understand, we have piles of solid evidence that the speed of light is constant. These observations confirmed a theoretical prediction made by special relativity, which can be summarized by …

treating space and time as a unified structure known as spacetime (with c relating the units of space and time), and requiring that physical theories satisfy a special symmetry called Lorentz invariance, whose mathematical formulation contains the parameter c. Lorentz invariance is an almost universal assumption for modern physical theories, such as quantum electrodynamics, quantum chromodynamics, the Standard Model of particle physics, and general relativity. As such, the parameter c is ubiquitous in modern physics, appearing in many contexts that are unrelated to light. For example, general relativity predicts that c is also the speed of gravity and of gravitational waves, and observations of gravitational waves have been consistent with this prediction.

So it seems that

• c happens to be the speed of many things, including light
• c does not depend on any characteristic of light waves or photons
• c follows from spacetime mathematics

But again, this is shaky ground for me. I’ll be happy to read corrections.

Ah, yes! Here, we have at least three entities:

1. source of light (at equator)
2. target satellite (North Pole)
3. observer(s)

The crucial question is, do they move relative to each other? If they all move together at c/2, their relative speed to each other is (compared to c: very close to) zero.

So in the context of an application like GPS, you do not want your satellite to smash into Earth at c/2, but have it in a stable orbit. Which means, it’s relative speed is very low. This is why I think the following is a misconception:

if you’re at the equator and send a signal to a satellite over the North Pole, it’s going to take twice as long as a signal sent across the same distance from the equator outwards.

Since both source and target move roughly at the same speed, the signal would take roughly the same amount of time even if the speed of light could be different.

Imagine being in a train and throwing a ball in the direction of movement, and in the opposite direction. As long as you target something in/on the train, it makes no difference. Similarly, the equator light source targeting an orbiting satellite does not care how fast the combined system is moving.

On top of that, the speed of light can not be different for different observers. It is the same for everyone, in each direction, in every motion. This is where relativity deviates from classical mechanics. In classical mechanics, we can make sense of things by imagining interacting billiard balls. Their individual speeds add up when they collide. In relativity, the speed of light is fixed. Nothing adds to it or subtracts from it.

Coming back to GPS: Even at these low relative speeds, there are still relativistic effects big enough to introduce significant errors in GPS positioning. We have to account for these errors: https://en.wikipedia.org/wiki/Error_analysis_for_the_Global_Positioning_System#Relativity

There’s a lot of factors that affect the timing of GPS… It’s built to be robust enough to handle it, and those factors are a lot more notable and common to be able to detect. Also, if there’s an inaccuracy in the speed of light, where it’s biased in one direction or another, it’s something we’ve experienced for our entire existence, and it’s not something we have detected as of yet, at least not in any measurable way by the current technology…

People smarter that you and I combined have worked on this, to great depth, already, and they haven’t found a significant enough issue to even mention it, nevermind publish something about it, and if they had, systems like GPS would have taken that inconsistency into account when designing the system… If they hadn’t, then it’s extremely likely that someone would have noticed when GPS was being made.

With all the intelligent people thinking about problems exactly like this and trying to figure things out for humanity already, I find it’s best to just take c at it’s value, and try not to think about it too much.