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When you see your image in a mirror what is bouncing back from the surface of the mirror?
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When you see your inage in a mirror are bouncing back from the surface of the mirror. This is what allows you to see your reflection?
The only way you can see yourself in a mirror is when there is light present. The ray of light hits the surface of the mirror and it reflects in your eyes. Which allows you to see you!
Is light bouncing off a mirror reflected or refracted?
Light bouncing off a mirror is reflected. Reflection is when the light bounces off a shiny surface back to your eye while refraction is when the light changes direction when passing from one medium to another medium of different optical density.
Why does the light falling on a mirror obey the laws of reflection?
The virtual image that seems to be behind the mirror is of the same size of the object from where the rays come from. The distance between the object and the mirror is the same distance between the mirror and the virtual image. The most notable difference is that the virtual image is reversed Mirrors have a very smooth surface with very few irregularities - unlike the surface of say paper - which may feel smooth to the touch but in fact is a very irregular surface if seen under a microscope. Light hitting an irregular surface is scattered in all directions so no image can be formed. Light hitting a mirror is reflected in the same order that it strikes the mirror - so an ordered reflection of the object is seen as a clear image. We see objects in a mirror, because a mirror, when hit by particles of light called photons, reflects the photons back to us and some reach, and enter, our eyes. Photons that hit a rough surface will bounce off of the surface in a haphazard manner, while those that hit a smooth surface, such as a mirror, only bounce off of the surface at the same angle at which they hit the object. The scientific term for this phenomenon is reflection. Not all smooth surfaces reflect photons back to us, even though, technically, they should bounce back at the same angle at which they hit the surface. This exception to the rule results, because some smooth surfaces absorb the light particles hitting them, making it impossible for them to bounce back. Another apparent exception to this rule is that, although our bodies are rough, uneven surfaces, off of which light bounces at random angles, our images reflect off of a mirror. The reason for this apparent contradiction is simply that when we stand in front of a mirror, some, but not all, of the light particles bouncing off of us will hit the smooth surface of the mirror. The ones that do reflect our images back to our eyes at exactly the same angle at which they hit the mirror. In other words, photons that bounce off of any part of our bodies and hit the mirror reflect back to our eyes from only one place on the mirror, and at only one angle. It follows that each point on our bodies that reflects back to our eyes from one point on the mirror produces an image in the mirror. All of the images together make up our reflections, like it or not. And remember that mirrors don't lie!
How does lateral inversion happen?
Lateral inversion is caused because the distance of the image behind the surface of a (flat) mirror is same as the distance that the object is in front of the mirror. So the image is reversed from "front to back". The image often APPEARS to be reversed sideways instead of front to back. "Lateral" means sideways.
The bouncing back of a wave as it meets surface or boundary is called?
hgjhgkft
How light travels when it hits a mirror?
it reflects back since mirror is a opaque surface .this phenomenon of bouncing back of light is called reflection.
When you see your inage in a mirror are bouncing back from the surface of the mirror. This is what allows you to see your reflection?
The only way you can see yourself in a mirror is when there is light present. The ray of light hits the surface of the mirror and it reflects in your eyes. Which allows you to see you!
How do we see images in a mirror?
Light 'bouncing' off the subject is reflected back by the mirror.
Why do you see your self in the mirror?
Mirrors have a special surface, usually at the back, that reflects light. This means that light that strikes the mirror's special surface bounces back. Light coming from you goes to the mirror's surface, bounces back and some of that light enters your eyes so that you are able to see your own image.
Is light bouncing off a mirror reflected or refracted?
Light bouncing off a mirror is reflected. Reflection is when the light bounces off a shiny surface back to your eye while refraction is when the light changes direction when passing from one medium to another medium of different optical density.
What happens to your image in a plane mirror?
your image reflects back
Why does the light falling on a mirror obey the laws of reflection?
The virtual image that seems to be behind the mirror is of the same size of the object from where the rays come from. The distance between the object and the mirror is the same distance between the mirror and the virtual image. The most notable difference is that the virtual image is reversed Mirrors have a very smooth surface with very few irregularities - unlike the surface of say paper - which may feel smooth to the touch but in fact is a very irregular surface if seen under a microscope. Light hitting an irregular surface is scattered in all directions so no image can be formed. Light hitting a mirror is reflected in the same order that it strikes the mirror - so an ordered reflection of the object is seen as a clear image. We see objects in a mirror, because a mirror, when hit by particles of light called photons, reflects the photons back to us and some reach, and enter, our eyes. Photons that hit a rough surface will bounce off of the surface in a haphazard manner, while those that hit a smooth surface, such as a mirror, only bounce off of the surface at the same angle at which they hit the object. The scientific term for this phenomenon is reflection. Not all smooth surfaces reflect photons back to us, even though, technically, they should bounce back at the same angle at which they hit the surface. This exception to the rule results, because some smooth surfaces absorb the light particles hitting them, making it impossible for them to bounce back. Another apparent exception to this rule is that, although our bodies are rough, uneven surfaces, off of which light bounces at random angles, our images reflect off of a mirror. The reason for this apparent contradiction is simply that when we stand in front of a mirror, some, but not all, of the light particles bouncing off of us will hit the smooth surface of the mirror. The ones that do reflect our images back to our eyes at exactly the same angle at which they hit the mirror. In other words, photons that bounce off of any part of our bodies and hit the mirror reflect back to our eyes from only one place on the mirror, and at only one angle. It follows that each point on our bodies that reflects back to our eyes from one point on the mirror produces an image in the mirror. All of the images together make up our reflections, like it or not. And remember that mirrors don't lie!
What type of image does a Convex mirror produce and Why?
A convex mirror produces a virtual image, because the principle light rays incident on the mirror surface from the object must pass through the focal point on the other side of the mirror (virtually), and so the image appears at a depth behind the mirror's surface. The three principle rays that form the focused image are: 1. The ray from the top of the object, parallel to the line passing through the center of the convex mirror, must pass through the focal point behind the mirror's surface. 2. The ray that passes from the top of the object and through the focal point in front of the mirror, comes through the mirror (virtually) parallel to the center line. 3. The ray that passes from the top of the object to the point where the surface of the mirror and the center line intersect, the reflection of which is traced back through the mirror's surface at the same angle as the reflected angle. The place behind the mirror where these rays intersect is the placement of the virtual image.
The bouncing back as it meets a surface or boundary is called what?
the rebound
How does lateral inversion happen?
Lateral inversion is caused because the distance of the image behind the surface of a (flat) mirror is same as the distance that the object is in front of the mirror. So the image is reversed from "front to back". The image often APPEARS to be reversed sideways instead of front to back. "Lateral" means sideways.
The bouncing back of a wave as it meets surface or boundary is called?
hgjhgkft
As you look at an ordinary mirror at large angle you can often see more than one image why?
In addition to the primary image formed by one reflection off the back of the mirror, you may get images formed after two reflections and a total internal refraction: reflection off the back of mirror, refraction on inside of front surface of glass and reflection off back of the mirror. The refraction will only take place at a large angle.
