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Thin Lens Equation 1

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Presentation on theme: "Thin Lens Equation 1 "β€” Presentation transcript:

1 Thin Lens Equation 1 𝑒 + 1 𝑣 = 1 𝑓

2 Terminology The focal length (f) of the lens is the distance from the centre of the lens to the focal point (F). Convex lens (converging) ο‚· focal length (f) F 1 𝑒 + 1 𝑣 = 1 𝒇 Concave lens (diverging) Convex lens: f is positive Concave lens: f is negative focal length (f) ο‚· ο‚· F F

3 Terminology The distance (u) is the distance from the object (O) to the centre of the lens Convex lens (converging) ο‚· focal length (f) F O u 1 𝒖 + 1 𝑣 = 1 𝑓 Concave lens (diverging) Convex lens: u is positive O Concave lens: u is positive focal length (f) ο‚· ο‚· u F

4 Terminology The distance (v) is the distance from the image (I) to the centre of the lens Convex lens (converging) ο‚· O u v 1 𝑒 + 1 𝒗 = 1 𝑓 I Concave lens (diverging) For both convex & concave lenses: v is positive if the image is on the opposite side of the lens to the object O I ο‚· ο‚· For both convex & concave lenses: v is negative if the image is on the same side of the lens as the object u F v

5 Example 1 Calculate the position and magnification of an image formed by a convex lens of focal length 20cm, when a 5cm high object is positioned 30cm in front of the lens. ο‚· 30 cm v 20 cm O v = ? u = 30 cm f = 20 cm 1 𝑒 + 1 𝒗 = 1 𝑓 I βˆ΄π‘£= 1 𝑓 βˆ’ 1 𝑒 βˆ’1 1 𝒗 = 1 𝑓 βˆ’ 1 𝑒 𝑣= βˆ’ βˆ’1 π‘€π‘Žπ‘”=βˆ’ 𝑣 𝑒 =βˆ’ =βˆ’2 = 60 cm Magnification = x2 (inverted image)

6 Example 2 Calculate the position and magnification of an image formed by a convex lens of focal length 10cm, when a 5cm high object is positioned 5cm in front of the lens. I ο‚· 5 cm v 10 cm v = ? u = 5 cm f = 10 cm O 1 𝑒 + 1 𝒗 = 1 𝑓 1 𝒗 = 1 𝑓 βˆ’ 1 𝑒 π‘€π‘Žπ‘”=βˆ’ 𝑣 𝑒 =βˆ’ βˆ’10 5 =+2 βˆ΄π‘£= 1 𝑓 βˆ’ 1 𝑒 βˆ’1 𝑣= βˆ’ βˆ’1 Magnification = x2 (upright image) = -10 cm

7 O I ο‚· 60 cm v 40 cm Example 3 Calculate the position and magnification of an image formed by a concave lens of focal length 40cm, when a 10cm high object is positioned 60cm in front of the lens. v = ? u = 60 cm f = -40 cm π‘€π‘Žπ‘”=βˆ’ 𝑣 𝑒 =βˆ’ βˆ’24 60 =+0.4 Magnification = x0.4 (upright image) 1 𝑒 + 1 𝒗 = 1 𝑓 1 𝒗 = 1 𝑓 βˆ’ 1 𝑒 βˆ΄π‘£= 1 𝑓 βˆ’ 1 𝑒 βˆ’1 𝑣= 1 βˆ’40 βˆ’ βˆ’1 = -24 cm

8 Example 4 Calculate the position and magnification of an image formed by a concave lens of focal length 40cm, when a 10cm high object is positioned 20cm in front of the lens. O I ο‚· 20 cm v 40 cm v = ? u = 20 cm f = -40 cm π‘€π‘Žπ‘”=βˆ’ 𝑣 𝑒 =βˆ’ βˆ’ =+0.67 Magnification = x0.67 (upright image) 1 𝑒 + 1 𝒗 = 1 𝑓 1 𝒗 = 1 𝑓 βˆ’ 1 𝑒 βˆ΄π‘£= 1 𝑓 βˆ’ 1 𝑒 βˆ’1 𝑣= 1 βˆ’40 βˆ’ βˆ’1 = cm

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