A meterstick lies along the optical axis of a convex mirror of focal length -44 cm,...

A convex mirror has a focal length of 3 cm. An object is placed 2 cm...

A convex mirror has a focal length of 3 cm. An object is placed 2 cm away from the mirror. The darkest lines on the grid represent 1 cm. (a) Draw the ray diagram and locate the image. Label the location of the focal point F, and the center of curvature. (b) Indicate the positive direction on the optical axis. Mark important locations on the optical axis, s, s’, f, r, and 0 (c) Indicate the magnification.

a convex mirror has a focal length of -20 cm. a. determine an object location for...

a convex mirror has a focal length of -20 cm. a. determine an object location for which the image will be one half the size of the object b. draw a ray diagram for this situation c. the mirror is replaced with a thin lens in exactly the same position. the image and object do not move. find the focal length of this thin lens.

A convex mirror has a focal length of −43 cm. An object is located 29 cm...

A convex mirror has a focal length of −43 cm. An object is located 29 cm from the surface of the mirror. Identify whether the characteristics of the image is real, inverted, virtual, upright (select the two that applies, and please explain why you selected the two). Thank you.

A concave mirror of focal length 15 cm is at x=0. An object is placed at...

A concave mirror of focal length 15 cm is at x=0. An object is placed at x=20 cm. A convex mirror of focal length 15 cm is at x=50 cm. Consider that light rays from the object strike the concave mirror first. Using the image formed by the concave mirror as the object, determine the location and magnification of the final image (formed by the convex mirror).

A candle is placed 23.33 cm in front of a convex mirror. When the convex mirror...

A candle is placed 23.33 cm in front of a convex mirror. When the convex mirror is replaced with a plane mirror, the image moves 7.0 cm farther away from the mirror. Find the focal length of the convex mirror. f =

A convex mirror has a focal length of -10 cm. What is the image distance si...

A convex mirror has a focal length of -10 cm. What is the image distance si if the image is upright and 1/2 the size of the object? (Be careful about the sign of the image distance.)

A diverging (convex) mirror has radius of curvature 5 cm. (a) What is its focal length?...

A diverging (convex) mirror has radius of curvature 5 cm. (a) What is its focal length? An object of size 1 cm is placed at distance (b) 5 cm and (c) 2.5 cm from the mirror. Calculate the distance and size of the image in each case, and state whether it's real or virtual. Draw ray diagrams to scale.

Two-Part Question: 1. A concave mirror has a focal length of 18 cm. The mirror forms...

Two-Part Question: 1. A concave mirror has a focal length of 18 cm. The mirror forms an image located 38 cm in front of the mirror. What is the magnification of the mirror? 2. A dentist’s mirror is placed 2.9 cm from a tooth. The enlarged image is located 5.8 cm behind the mirror. (a) What kind of mirror (plane, concave, or convex) is being used? (b) Determine the focal length of the mirror. (c) What is the magnification? (d)...

Answer completely and correctly for good rating. A convex mirror has a radius of curvature whose...

Answer completely and correctly for good rating. A convex mirror has a radius of curvature whose magnitude is 51 cm. The mirror is positioned on a horizontal optical bench with its front surface at 0 cm. A 7.0 cm long fluorescent lamp oriented vertically is placed at +108 cm. 1.)What is the focal length of the mirror? 2.)At what distance from the mirror can we find a sharp image of the lamp? Tries 0/5 How tall is the image of...

A concave mirror has a focal length of 31.4 cm. The distance between an object and...

A concave mirror has a focal length of 31.4 cm. The distance between an object and its image is 58.6 cm. Find (a) the object and (b) image distances, assuming that the object lies beyond the center of curvature and (c) the object and (d) image distances, assuming that the object lies between the focal point and the mirror.