Please compare the experimental values of the focal length of the concave lens from the two figures. Please calculate the relative deviation in focal lengtth with respect to the value obtained from the yellow table. Please explain how you got this value. Concave-convex lens combination "in-contactDistance of object from the lenses (cm)Distance of image from the lenses (cm)Equivalent focal length of the lenses (cm)Calculated magnification of the image (compared to theoriginal object)Measured magnification of final image (compared to theoriginal object)Experimental focal length of the concave leas (cm)Theoretical focal length of the concave lens (cm)Percent Deviation (%)30.821.512.63-0.7-0.778-1820.29 Concave-Convex lens combination "not in contactDistance of object from convex lens 1 (cm)Distance of first image from convex lens 1 (cm)Measured magnification of first imageDistance of convex lens 1 from concave lens (cm)Distance of first image from the concave lens (cm)Distance of final image from the concave lens (cm)Calculated magnification of final image (compared to theoriginal object)Reduced/Magnified?Real/Virtual?Upright/Inverted?Experimental focal length of the concave lens (cm)Description offinal imageTheoretical focal length of the concave lens (cm)Percent Deviation (%)13.316.51010.5MagnifiedRealInverted-1513.7

Focal length of a lens measures the ability of a lens to converge or diverge the light rays. The…

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