Magnifying light speed Questions

at the speed of light your time stops.
If you moving very close to the speed of light then things in front of you that you approach will be changing very fast (live and age in an eye blink) and the things you leave behind you will look almost freezed (passing very slowly)

mirror in front of you (that travels together with you) will give you reflection up until the very speed of light. At the speed of light the mirror will be at zero distance from you and give you immediate reflection of your current state (or you can treat it as giving no reflection) When space becomes flat there is no space to speak about moving back and forth and reflecting anything (i mean in the direction of your movement)?

The more interesting question here is this: if you put a clock in front of your mirror and try to compare the clock in your hand and the clock-reflection that comes back. will both show the same time ? What the difference will be ? will it be changing (decreasing increasing) if you move faster ?

i don't see how it would be different in any way from what you see when you do not move. Have in mind that when you move at speed close to speed of light the things in front of you that you are approaching get magnified by themselves (well not exactly magnified but they approach you and it looks like they stretch out from the destination point of your movement) - well in normal situation when you look at road in front of you it looks narrowing the farther you look , at the speed of light however it will not look narrowing - it will look equally wide at any distance ahead. So for magnifying glass there is nothing to magnify because all distances ahead of you become zero - collapse to the plane perpendicular to the direction of your movement.

At this point i would like to mention wave-function collapse paradox.
If you look at two entangled photons moving in opposite directions and then detect one's polarization immidiately knowing that the other's one polarization must be perpendicular. This looks for you as faster than light collapse of wave function. But for those photons the space is flat and they are still at zero distance from each other. Could this provide a solution to the paradox ? Look at paradox from photons point of view ;)

sorry i don't get your question. You mean how an outside observer would monitor your motion ? the observer that is standing still ahead of you will not see you until the very moment you reach him (interestingly if Jesus Christ arrives in the light-speed spaceship to earth we will have no warning before his arrival - he would indeed come as promissed in the bible - unexpectedly without prior warning ). Incoming at light speed objects cannot be seen in advance so we can get unexpected incoming at any moment (and actually some scientists were warning us about incoming very fast objects from the milky way central parts).
The observer staying behind you will see you freezed (when you move at close to speed of light the objects that you run away from they will look almost freezed and from those objects standpoint you will also seem to be changing very slowly)