(8) In triangle \( A B C \) the angle at \( B \) is \( 90^{\circ} \). If \( \mathrm{BC}=23 \mathrm{~mm} \) and \( \mathrm{AB}=37 \mathrm{~mm} \) find the size of the angle at C in degrees. angle \( \mathrm{C}= \)

To find the size of angle \( C \) in degrees in triangle \( ABC \) where angle \( B \) is \( 90^{\circ} \), we can use the trigonometric ratios in a right-angled triangle. Given: - \( \mathrm{BC} = 23 \, \text{mm} \) - \( \mathrm{AB} = 37 \, \text{mm} \) We can use the tangent function to find the angle \( C \): \[ \tan(C) = \frac{\text{opposite side}}{\text{adjacent side}} \] In this case, the opposite side is \( \mathrm{AB} \) and the adjacent side is \( \mathrm{BC} \). Therefore, we have: \[ \tan(C) = \frac{37}{23} \] To find the angle \( C \) in degrees, we can use the inverse tangent function: \[ C = \arctan\left(\frac{37}{23}\right) \] Let's calculate the value of \( C \) in degrees. Calculate the value by following steps: - step0: Calculate: \(\arctan\left(\frac{37}{23}\right)\) The angle \( C \) in degrees is approximately \( 1.01463 \) radians. To convert this to degrees, we can use the conversion factor where \( 1 \, \text{radian} = 57.29577951 \, \text{degrees} \). Therefore, the angle \( C \) in degrees is approximately \( 1.01463 \times 57.29577951 \approx 58.0 \) degrees.