A skydiver weighing 200 lbs with clothes that have a drag coefficient of 0.325 is falling in an area with an atmospheric density of 1.225 kg/m² (assuming that altitude has a negligible effect on atmospheric density).

The skydiver can change body orientation from:

Straight-erect with a cross-sectional area of 6 sq ft.
Belly-flat with a cross-sectional area of 24 sq ft.
Calculate the terminal velocity of the person in both orientations:

A. Straight-erect
B. Belly-flat

Question

A skydiver weighing 200 lbs with clothes that have a drag coefficient of 0.325 is falling in an area with an atmospheric density of 1.225 kg/m² (assuming that altitude has a negligible effect on atmospheric density).

The skydiver can change body orientation from:

Straight-erect with a cross-sectional area of 6 sq ft.
Belly-flat with a cross-sectional area of 24 sq ft.
Calculate the terminal velocity of the person in both orientations:

A. Straight-erect
B. Belly-flat

StudyXY · Accepted Answer

I'll solve this problem step by step, carefully following the LaTeX formatting guidelines: : Identify the Terminal Velocity Formula : Convert Units : Calculate Terminal Velocity for Straight-Erect Position : Calculate Terminal Velocity for Belly-Flat Position A. Straight-erect terminal velocity: $56.03 \frac{m}{s}$ B. Belly-flat terminal velocity: $35.36 \frac{m}{s}$ Key Insights: - Increasing cross-sectional area reduces terminal velocity - Drag coefficient and body orientation significantly impact terminal velocity - The skydiver falls much slower in the belly-flat position due to increased air resistance

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I'll solve this problem step by step, carefully following the LaTeX formatting guidelines:

Step 2
: Identify the Terminal Velocity Formula

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