-di/do
-p/q
hi/ho
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 magnification equation for a convex mirror is given by: M = -1 / (1 - d/f), where M is the magnification, d is the object distance, and f is the focal length of the mirror. The negative sign indicates that the image formed is virtual and upright.
When you move your face away from a concave mirror, the image you see in the mirror will become smaller and eventually disappear as you move further away from the focal point of the mirror. This is because the magnification effect of the concave mirror is strongest when objects are close to the mirror's focal point.
One example of a concave mirror is a shaving or makeup mirror. These mirrors curve inward, causing light rays to converge to a focal point. This type of mirror is commonly used in applications where magnification or focusing of light is required.
Convex is () and makes objects appear larger. Concave is )( and makes objects appear smaller. The side rear-view mirrors on cars have concave mirrors, hence, "Object are closer than they appear." Easy way to remember is that a cave is like a hole in the ground, so something is concave if it gets smaller towards the center.
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 magnification equation for a convex mirror is given by: M = -1 / (1 - d/f), where M is the magnification, d is the object distance, and f is the focal length of the mirror. The negative sign indicates that the image formed is virtual and upright.
When you move your face away from a concave mirror, the image you see in the mirror will become smaller and eventually disappear as you move further away from the focal point of the mirror. This is because the magnification effect of the concave mirror is strongest when objects are close to the mirror's focal point.
you can get concave mirrors especially from school's science equipments suppliers.
One example of a concave mirror is a shaving or makeup mirror. These mirrors curve inward, causing light rays to converge to a focal point. This type of mirror is commonly used in applications where magnification or focusing of light is required.
no concave mirror is in shape of concave mirror
why do we use concave mirror as converging mirror
Convex is () and makes objects appear larger. Concave is )( and makes objects appear smaller. The side rear-view mirrors on cars have concave mirrors, hence, "Object are closer than they appear." Easy way to remember is that a cave is like a hole in the ground, so something is concave if it gets smaller towards the center.
A concave mirror is typically used in a simple microscope. This mirror helps in reflecting and focusing light onto the specimen, allowing for magnification and viewing of small objects.
A concave mirror is used in microscopes because it can magnify the image formed without causing much distortion, resulting in better clarity and resolution. The mirror reflects and converges light rays to focus them effectively, allowing for higher magnification in microscopes. Convex lenses are also used in microscopes to work together with the concave mirror, as they help correct any aberrations in the image and provide additional magnification.
concave mirrors. These mirrors have a curved surface that reflects and converge light rays to focus the image. The focal point of the mirror determines the magnification of the image.
real, inverted and magnification less than one