What is the nature of linear magnification of a convex mirror
The magnification equation for a concave mirror is given by the formula: M = - (image distance) / (object distance), where M is the magnification, image distance is the distance from the mirror to the image, and object distance is the distance from the mirror to the object. Negative magnification indicates an inverted image.
The magnification of a convex mirror is always positive because the image formed is virtual and upright. The magnification is less than 1 because the image is diminished in size compared to the object. This is due to the diverging nature of convex mirrors, causing the rays to spread out and create a smaller image.
To calculate the image position when given magnification by a concave mirror, you can use the mirror equation: 1/f = 1/d_o + 1/d_i, where f is the focal length of the mirror, d_o is the object distance, and d_i is the image distance. Magnification, M, is also given by -d_i/d_o. By substituting the values of magnification and focal length into the mirror equation, you can solve for the image distance and then determine the image position.
The mirror in this case is a convex mirror, as virtual images are formed by convex mirrors.
To determine the magnification of a mirror, divide the height of the image by the height of the object. The result will be the magnification factor.
The magnification factor (m) for a convex mirror is defined as the ratio of the image height (h') to the object height (h), expressed as ( m = \frac{h'}{h} ). For a convex mirror, the magnification is always positive and less than 1, indicating that the image is virtual, upright, and smaller than the object. The formula for magnification can also be expressed in terms of the object distance (u) and the image distance (v) as ( m = -\frac{v}{u} ), where both v and u are negative for a convex mirror.
The magnification equation for a concave mirror is given by the formula: M = - (image distance) / (object distance), where M is the magnification, image distance is the distance from the mirror to the image, and object distance is the distance from the mirror to the object. Negative magnification indicates an inverted image.
The magnification of a convex mirror is always positive because the image formed is virtual and upright. The magnification is less than 1 because the image is diminished in size compared to the object. This is due to the diverging nature of convex mirrors, causing the rays to spread out and create a smaller image.
A convex mirror will always create a virtual image. It will also have a negative magnification. The passenger side mirror in every car is slightly convex. [The one with "Objects in Mirror are closer than they appear"] Also, anti-theft mirrors in convenience stores have these properties.
A convex mirror will always create a virtual image. It will also have a negative magnification. The passenger side mirror in every car is slightly convex. [The one with "Objects in Mirror are closer than they appear"] Also, anti-theft mirrors in convenience stores have these properties.
No; I have a convex mirror that is a x 10 magnification, great for plucking eyebrows I can tell you and it is curved.
convex mirror
To calculate the image position when given magnification by a concave mirror, you can use the mirror equation: 1/f = 1/d_o + 1/d_i, where f is the focal length of the mirror, d_o is the object distance, and d_i is the image distance. Magnification, M, is also given by -d_i/d_o. By substituting the values of magnification and focal length into the mirror equation, you can solve for the image distance and then determine the image position.
The mirror in this case is a convex mirror, as virtual images are formed by convex mirrors.
it is a convex mirror as it produces diverging waves
since the convex mirror is curved outwards the the focus is behind the mirror
To determine the magnification of a mirror, divide the height of the image by the height of the object. The result will be the magnification factor.