Deck 2: Common Measurements in Exercise Physiology

A) increases as the power output increases.
B) decreases as the power output increases.
C) remains constant as the power output increases.
D) increases as the power output decreases.

A) Newtons.
B) joules.
C) watts.
D) joules per second.

A) subject's body weight.
B) resistance against flywheel.
C) pedaling speed.
D) exercise time.

A) resting VO₂.
B) 50% of resting VO₂.
C) 200% of resting VO₂.
D) VO₂ max.

A) 10 watts
B) 660 watts
C) 36,000 watts
D) Power cannot be calculated with the information provided.

A) 10 ml.kg^-1.min^-1.
B) 25 ml.kg^-1.min^-1.
C) 35 ml.kg^-1.min^-1.
D) 45 ml.kg^-1.min^-1.

A) the VO₂ of running is always the same.
B) the VO₂ of horizontal running is always 1 MET.
C) the VO₂ increases linearly with running speed.
D) none of the above.

A) joule.
B) watt.
C) kpm.
D) kcal.

A) the ability to perform work.
B) work divided by time.
C) work times force.
D) force times distance.

A) work output/energy expended at rest times 100.
B) work performed/energy expended above rest times 100.
C) work output/energy expended times 100.
D) energy expended/work output times 100.

A) oxygen consumption.
B) heat production.
C) ATP hydrolysis.
D) carbon dioxide production.

A) the ability to transform energy from one state to another.
B) the ability to utilize oxygen.
C) force times distance.
D) distance times power output.

A) have a higher percentage of fast muscle fibers.
B) have a higher percentage of slow muscle fibers.
C) have 50% fast fibers and 50% slow fibers.

A) a lower VO₂ at any given running speed compared to an economical runner.
B) a higher VO₂ at any given running speed compared to an economical runner.
C) the same VO₂ at any given running speed compared to an economical runner.

A) increases
B) does not change
C) decreases

A) closed-circuit spirometry.
B) open-circuit spirometry.
C) direct calorimetry.
D) computer calorimetry.