c)Our final figure modeling the forearm is the most realistic so far, showing that the brachioradialis inserts much lower on the upper arm, h₂ = 3 cm, than the biceps brachii. This will significantly shorten the brachioradialis' moment arm. The muscle attachment lengths on the forearm and the biceps attachment on the upper arm are the same as before: d₁ = 3 cm, d₂ = 15 cm, and d3 = 34 cm and h = 20 cm. M₁ h₂ d M₂ dz d₂ W Calculate the new ratio of the mechanical advantage of the brachioradialis to the mechanical advantage of the biceps. Ratio of Mechanical Advantage MA₂ =) = MA₁

c)Our final figure modeling the forearm is the most realistic so far, showing that the brachioradialis inserts much lower on the upper arm, h₂ = 3 cm, than the biceps brachii. This will significantly shorten the brachioradialis' moment arm. The muscle attachment lengths on the forearm and the biceps attachment on the upper arm are the same as before: d₁ = 3 cm, d₂ = 15 cm, and d3 = 34 cm and h = 20 cm. M₁ h₂ d M₂ dz d₂ W Calculate the new ratio of the mechanical advantage of the brachioradialis to the mechanical advantage of the biceps. Ratio of Mechanical Advantage MA₂ =) = MA₁

Elements Of Electromagnetics

7th Edition

ISBN:9780190698614

Author:Sadiku, Matthew N. O.

Publisher:Sadiku, Matthew N. O.

ChapterMA: Math Assessment

Section: Chapter Questions

Problem 1.1MA

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