For a biconvex thin lens, choose a radius of curvature somewhere between 10 and 100 centimeters (and different than you did for a converging mirror), then choose three different object distances (at least one inside the focal length, one between the focal length and the center of curvature, and one beyond the center of curvature), and for each locate the image using the thin lens equation and determine the image magnification. Also, draw a nice, neat ray diagram that matches the equations, and labels all the relevant points and distances. Finally, for each, describe the image characteristics as either real or virtual, upright or inverted, and either larger or smaller.

For a converging mirror, choose a radius of curvature somewhere between 10 and 100 centimeters, then choose three different object distances (at least one inside the focal length, one between the focal length and the center of curvature, and one beyond the center of curvature), and for each locate the image using the spherical mirror equation and determine the image magnification. Also, draw a nice, neat ray diagram that matches the equations, and labels all the relevant points and distances. Finally, for each, describe the image characteristics as either real or virtual, upright or inverted, and either larger or smaller.

For a converging mirror, choose a radius of curvature somewhere between 10 and 100 centimeters, then choose three different object distances (at least one inside the focal length, one between the focal length and the center of curvature, and one beyond the center of curvature), and for each locate the image using the spherical mirror equation and determine the image magnification. Also, draw a nice, neat ray diagram that matches the equations, and labels all the relevant points and distances. Finally, for each, describe the image characteristics as either real or virtual, upright or inverted, and either larger or smaller.

For a diverging mirror, choose a radius of curvature somewhere between 10 and 100 centimeters, then choose three different object distances (at least one inside the focal length, one between the focal length and the center of curvature, and one beyond the center of curvature), and for each locate the image using the spherical mirror equation and determine the image magnification. Also, draw a nice, neat ray diagram that matches the equations, and labels all the relevant points and distances. Finally, for each, describe the image characteristics as either real or virtual, upright or inverted, and either larger or smaller.