Neptune

Taking the approximate gravitational lensing formula, , and plugging in the sun's mass, 1.9884*1030 kg, and the sun's radius 6.955*108 m the approximate value of the angle is 0.00000849240953508 radians. Then making a resultant velocity triangle and doing trigonometry helps find the rest of the values needed to find the Lorentz factor on the surface of the sun. since light was already travelling at the speed of light, and the speed of light is constant and cannot be exceeded, the time of the resultant ray of light is dilated compared to the ray's original path. The last step is to divide the speed of light by segment b of the triangle to get the approximate Lorentz factor for the surface of the sun.

If the dimensional analysis of it was why does it still give me G when I do this?

Yes I am sincerely serious

You can solve the radius of a gravitational body depending on the gravity of the surface. Of course the gravity of the surface of a photon is the gPhoton equation. That's what In this picture. My photon radius and the approach just mentioned above being equal should leave you doubtless. It's not only for green photons if that's your next question, but if you want to ask me to prove that too I will.

F is a constant I like to call Flavio's Constant after my First name I my equations came from Physics equations that I combined and then simplified. As for testing I've only solved them mathematically to my knowledge to be real, experimentally it's up for grabs Does this help you better grasp it? I did the calculations for a visible green frequency photon.

I wanted to share a few Algebraic physics formulas, a couple I created and other established ones, and wanted to get the community's reaction and input. Also if the my ideas get big, I want to call them Neo-Classical Physics. Incase it isn't obvious the ones I created are the rPhoton and gPhoton formulas. I'd like to ask you to review them with your own inputs of different photon frequencies or wavelengths to find errors of them, if any. And I forgot to write the E=mc2 formula in the picture but it will be needed to prove my formulas right or wrong. You'll need it in the m=E/c2 form. Enjoy.