Answer :
Explanation:
Certainly! Here's a diagrammatic representation of a beam of rays parallel to the principal axis incident on a convex mirror, and their path after reflection:
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| Principal Axis (PA)
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```
In the diagram:
- The convex mirror is represented by a curved surface with its center of curvature and principal axis not explicitly drawn for simplicity.
- The incident rays are shown as parallel to the principal axis (PA).
- After reflection from the convex mirror, the rays diverge. They appear to diverge away from the focal point (F) behind the mirror.
This diagram illustrates how parallel rays incident on a convex mirror reflect and diverge.
Answer:
Certainly! Let me describe the path of the parallel rays incident on a convex mirror and their reflection. Here's a diagrammatic representation:
1. **Incident Ray**: Draw a ray parallel to the principal axis from the top of the object (which is at infinity) towards the mirror. This ray will be reflected by the mirror.
2. **Reflected Ray**: To find the reflected ray, draw a line from the point where the incident ray intersects the mirror to the focal point (F) of the mirror. The reflected ray will be parallel to the principal axis after reflection.
3. **Focal Point (F)**: The focal point is located halfway between the mirror's vertex (V) and its center of curvature (C).
4. **Image Formation**: Extend the reflected ray behind the mirror. The point where the extended reflected ray intersects the principal axis is the virtual image formed by the convex mirror.
Remember that convex mirrors always produce virtual, diminished, and erect images. If you have any more questions or need further clarification, feel free to ask!
Explanation: