Q4. Once you have drawn in the three principal rays, insert a line with an arrowhead to represent the image. Is the image real or virtual? (Highlight one) Is the image upright or inverted? (Highlight one) Is the image magnified or reduced? (Highlight one) If each small square of the “graph paper" of Figure 4 you just used is 1cm in length, carefully measure the following: f= 4cm do = 3.5cm ho = 3cm di = hi = 1.5cm Using thin lens Equations 1 and 2, calculate d; and M. Show your work and clearly highlight your answers: either use the equation editor or take a photo of your work and insert it. Insert your work here Q5. Do your calculated and measured values for di and M agree? Explain discrepancies and correct if necessary.

Hello,

I need help with Q4 and Q5.

Thank you!

Transcribed Image Text:

**Q4.** Once you have drawn in the three principal rays, insert a line with an arrowhead to represent the image. - Is the image **real** or **virtual**? (**Highlight** one) - Is the image **upright** or **inverted**? (**Highlight** one) - Is the image **magnified** or **reduced**? (**Highlight** one) If each small square of the “graph paper” of Figure 4 you just used is 1 cm in length, carefully measure the following: - \( f = 4 \, \text{cm} \) - \( d_o = 3.5 \, \text{cm} \) - \( h_o = 3 \, \text{cm} \) - \( d_i = \) - \( h_i = 1.5 \, \text{cm} \) Using thin lens Equations 1 and 2, **calculate** \( d_i \) and \( M \). Show your work and clearly highlight your answers: either use the equation editor or take a photo of your work and insert it. *Insert your work here* **Q5.** Do your calculated and measured values for \( d_i \) and \( M \) agree? Explain discrepancies and correct if necessary.

Transcribed Image Text:

**Figure 4**: This is a ray tracing diagram illustrating the behavior of light as it passes through a converging lens. The setup involves an object placed to the left of the lens, marked as "object." The focal points (Fo and Fi) are indicated on either side of the lens. In this scenario, the object distance (\(d_o\)) is less than the focal length (\(f\)) of the lens. **Diagram Explanation:** - **Converging Lens:** The central element in the diagram is the lens depicted as an oval shape. - **Principal Axis:** A horizontal line runs through the center of the lens, along which the focal points are located. - **Focal Points:** Labeled as Fo (Focal point on the object side) and Fi (Focal point on the image side). - **Rays:** Three violet rays illustrate the path of light: - **First Ray:** Travels parallel to the principal axis, refracts through the lens, and passes through the focal point (Fi) on the other side. - **Second Ray:** Passes straight through the center of the lens without deviation. - **Third Ray:** Aimed towards the focal point (Fo) on the object's side, refracts through the lens, and exits parallel to the principal axis. The diagram helps visualize how the lens focuses light to form a virtual image for this configuration, where the object is positioned closer to the lens than the focal length.