yes

because the sun’s gravity on you is counter to that of earth’s

during the day

That's simply not true

Do an experiment to however many degrees of accuracy with whatever resolution, you will not see the weight of a 1kg ball weigh differently at day or at night

I have stated before that the weight difference is almost zero

Do you guys think the other planets are flat too? Or do you think they don’t exist

@Superiorna_Artiljerija it's not almost zero

Holy hell your pfp

It's exactly zero

The sun’s gravitational acceleration has an effect on both you and the earth, however the earth’s pull has much stronger relative effect of the sun

The difference in weight

Try this experiment yourself

How could the sun have an effect on the earth but not you?

Try this experiment yourself

I bet you $10 there's no difference

H

Flat Earthers please explain something to me:

Round earthers explain my observation first

What observation, hgb?

I want to know how travel works. If you are get in an airplane in Japan and take it to Hawaii, how come it takes less time than flying from the U.S.A to Russia?

The same mass weighs the same day or night

What are you trying to prove?

I think Floortugal explained it well, hgb.

I’m doing more research on it

I’m not entirely correct

Heh

However

@MAV

It's definitely explainable in both flat earth and round earth scenarios, this particular observation.

Ahh, don't you just love how warped the land masses are in the FE model

I am actually wrong

I pulled a small brain

Inverse square law beat me up for lunch money

While you are indeed being pulled towards the sun, the earth is also being pulled along with you

That's the Azimuthal equidistant, Juno. It's a genuine map projection that was sort of adopted by the flat earthers.

Indeed

they'll admit it's probably not exactly like the projection in actuality.

But is inaccurate on the lateral axis

But like how does mars work exactly in the flat earth theory

Azimuthal projections are used in aircraft for range