Now, let me ask you this. What would be the strategic advantage of seeing an enemy ship a few (milli) seconds earlier? Especially in the 17th century.
Also, if it is correct, what does it mean that a telescope allows us to see distant objects in real time? — Hachem

If we link these thoughts to the original discussion then we can wonder whether we are seeing the stars because their light takes time to reach our eyes, or if we see them just like we see a light on earth that does not shine beyond a very limited distance. — Hachem

what would determine the difference between the time the admiral detects the ship, and the time in which the lower officer does the same in turn? It is in fact a very simple operation: if the difference is equal to the time it takes the ship to get in visual range of the naked eye, then we can say that the telescope is showing the location of the ship in real time. If, on the other hand, the difference between the detection times is negligible, then we can say that the telescope allows us to see objects not there where they are, but where they were when their light started its travel towards us. — Hachem

First, diffraction should not be a problem since we are talking about a 0.25mm aperture, with no lens. The different wavelengths are measured in nanometers. — Hachem

Concerning your objection about my Rømer analysis you are assuming that which I think he had no right to do. If you assume that you are seeing the moment when a moon appears from behind Jupiter you have already decided that the difference between the times of observations can only come because of the distance and the speed of light. I do not know how to make it any clearer, but this obviously, as least to me, the case of a circular argument. Your theory has to be right for it to be right. — Hachem

Your theory has to be right for it to be right. — Hachem

1. The pinhole lens has a Nikon fitting but is not made by Nikon. — Hachem

2. Your assumption of diffraction is not reasonable, Why should a collimated beam diffract when going through an empty opening? — Hachem

3. Even assuming diffraction, the question still remains of why there should be such differences between the different images on the basis of shutter speed alone. I would very much like to see some calculations that take the speed of light into consideration, and explain to me the differences. — Hachem

4. You are defending the theory or theories of light as they are taught. I have no problem with that. But referring to them is not enough. I will be very happy and obliged if you could show me where I went wrong, but appealing to authority is not enough. — Hachem

I do not think that. Therefore, I say that the theory of light cannot explain vision and certainly cannot explain the fact that when we look through a telescope the object is there where we see it, when we see it. The same way we look at somebody coming down the road, still a few hundred meters away from us, and we know it will take some time for him to reach us. Light theory as it is can easily explain this last example, but it breaks when it comes to distant objects and great distances. — Hachem

Quote what you do not agree with and say why you do not agree with it instead of simply asking again and again for clarifications. — Hachem

The question is whether the differences in the times of eclipse and reappearance of the moon cannot be interpreted differently, without involving the idea that it takes time for light to travel through space. (1) We all know that when looking through the telescope at a planet like Jupiter, we do not see it rotating about its axis, or orbiting the sun. (2)We get each time a snapshot of a frozen moment in time, and the changes to the images we receive occur in jumps without any intermediate states. (3) This is understood as the effect of parallax, or more simply resolution. Because of the distance two points separated by relatively large distances will appear to our perception as one, and it takes time before we notice the difference between one position and another.

This is exactly the situation which Rømer is analyzing, but instead of understanding it as a case of parallax and resolution, he chooses a very specific approach. He considers the time it takes for astronomers to observe the disappearance or reappearance of Jupiter's moon as a fact that needs no further explanation. If we see the moon appearing at time t that is because the moon appeared at time t. And if we notice that when the earth is at another position, farther from Jupiter, and the moon appears or disappears at time t+x, then x must be caused by the longer distance between the earth and Jupiter. (4)This is much too easily discounting the fact that we only see immediately the differences between one view and another when we are very close to the object. (5)It is not surprising that Jupiter's moon seems to appear or disappear at a later time than when the earth is closer to Jupiter. The larger the distance between the earth and Jupiter, the more time it will take us to notice a difference between two consecutive moments. — Hachem

I can see that your argument rests entirely on the assumption that "it takes longer to notice changes in distant objects" despite the obvious fact that bigger telescopes mean more resolution, which can eliminate any setbacks caused by resolution blur. The "no intermediate states" bit is unsubstantiated and must result from a confused understanding of how we carry out astronomical observations... — VagabondSpectre