m= lo0g R-30cm hz Qy 12M 16. Calculate the moment of inertia for the wheel using equation 4.

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Use the bottom values as they are the average.

Here is the transcribed data from the table, typically found in a physics or motion study context. The table includes initial and final positions, accelerations, initial and final velocities, and average values:

| \(y_i\) (m) \(t = 0.4 \, \text{s}\) | \(y_f\) (m) \(t = 0.8 \, \text{s}\) | \(a \, (\text{m/s}^2)\) from \(y\) vs \(t\) graph | \(v_i \, (\text{m/s})\) \(t = 0.4 \, \text{s}\) | \(v_f \, (\text{m/s})\) \(t = 0.8 \, \text{s}\) | \(a \, (\text{m/s}^2)\) from \(v_y\) vs \(t\) graph |
|------------------------------------|-----------------------------------|-----------------------------------|----------------------------|----------------------------|-----------------------------------|
| 125 m                              | 290 m                             | 412.5 \(\text{m/s}^2\)            | 30 \(\text{m/s}\)          | 746 \(\text{m/s}\)         | 942.5 \(\text{m/s}^2\)            |
| 120 m                              | 345 m                             | 562.5 \(\text{m/s}^2\)            | 365 \(\text{m/s}\)         | 670 \(\text{m/s}\)         | 762.5 \(\text{m/s}^2\)            |
| 115 m                              | 290 m                             | 437.5 \(\text{m/s}^2\)            | 370 \(\text{m/s}\)         | 580 \(\text{m/s}\)         | 525 \(\text{m/s}^2\)              |

### Average Values:
- Average Initial Position: \(121.67 \, \text{m}\)
- Average Final Position: \(308.33 \, \text{m}\)
- Average Acceleration from \(y\) vs \(t\) graph: \(470.83 \, \text{m/s}^2\)
- Average Initial Velocity: \(358.33 \
Transcribed Image Text:Here is the transcribed data from the table, typically found in a physics or motion study context. The table includes initial and final positions, accelerations, initial and final velocities, and average values: | \(y_i\) (m) \(t = 0.4 \, \text{s}\) | \(y_f\) (m) \(t = 0.8 \, \text{s}\) | \(a \, (\text{m/s}^2)\) from \(y\) vs \(t\) graph | \(v_i \, (\text{m/s})\) \(t = 0.4 \, \text{s}\) | \(v_f \, (\text{m/s})\) \(t = 0.8 \, \text{s}\) | \(a \, (\text{m/s}^2)\) from \(v_y\) vs \(t\) graph | |------------------------------------|-----------------------------------|-----------------------------------|----------------------------|----------------------------|-----------------------------------| | 125 m | 290 m | 412.5 \(\text{m/s}^2\) | 30 \(\text{m/s}\) | 746 \(\text{m/s}\) | 942.5 \(\text{m/s}^2\) | | 120 m | 345 m | 562.5 \(\text{m/s}^2\) | 365 \(\text{m/s}\) | 670 \(\text{m/s}\) | 762.5 \(\text{m/s}^2\) | | 115 m | 290 m | 437.5 \(\text{m/s}^2\) | 370 \(\text{m/s}\) | 580 \(\text{m/s}\) | 525 \(\text{m/s}^2\) | ### Average Values: - Average Initial Position: \(121.67 \, \text{m}\) - Average Final Position: \(308.33 \, \text{m}\) - Average Acceleration from \(y\) vs \(t\) graph: \(470.83 \, \text{m/s}^2\) - Average Initial Velocity: \(358.33 \
Certainly! Here's the transcription:

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**16. Calculate the moment of inertia for the wheel using equation 4.**

\( I = \frac{BR}{(mg - mh)} \)

- \( m = 100 \, \text{g} \)
- \( R = 30 \, \text{cm} \)
- \( h = 122 \, \text{m} \)

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Note: The expression for the moment of inertia \( I \) involves constants B, R, and measurements related to mass \( m \) and height \( h \) in the context of this calculation. The specific context or background for the variables such as \( B \) is not provided in the image.
Transcribed Image Text:Certainly! Here's the transcription: --- **16. Calculate the moment of inertia for the wheel using equation 4.** \( I = \frac{BR}{(mg - mh)} \) - \( m = 100 \, \text{g} \) - \( R = 30 \, \text{cm} \) - \( h = 122 \, \text{m} \) --- Note: The expression for the moment of inertia \( I \) involves constants B, R, and measurements related to mass \( m \) and height \( h \) in the context of this calculation. The specific context or background for the variables such as \( B \) is not provided in the image.
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