MCQsLlearn App Download MCQsLearn Free App
As an Amazon Associate I earn from qualifying purchases.

Applied Physics: Vectors Questions and Answers PDF Download eBook - 114

Applied Physics Vectors trivia questions and answers, applied physics vectors quiz answers PDF 114 to practice applied physics exam questions for online classes. Practice "Vector and Equilibrium" trivia questions and answers, applied physics vectors Multiple Choice Questions (MCQ) to practice physics test with answers for online college degrees. Free applied physics: vectors MCQs, angular and linear velocities, work done formula, physics equations, geostationary orbits, applied physics: vectors test prep for colleges that offer online degrees.

"Physical quantities having both magnitude and directions are called", applied physics vectors Multiple Choice Questions (MCQ) with choices scalar quantities, vector quantities, mental quantities, and both a and b for SAT practice test. Learn vector and equilibrium questions and answers for online college courses. Applied Physics: Vectors Video

Trivia Quiz on Applied Physics: Vectors PDF Download eBook

Applied Physics: Vectors Quiz

MCQ: Physical quantities having both magnitude and directions are called

  1. vector quantities
  2. scalar quantities
  3. mental quantities
  4. both a and b

A

Geostationary Orbits Quiz

MCQ: Geo-stationary satellites are useful examples of

  1. satellite motion
  2. satellite motion
  3. satellite gravity
  4. satellites

A

Physics Equations Quiz

MCQ: If a body moving with initial, constant velocity of 10 m s-1, accelerates for 2 seconds at a constant rate of 12 m s-2, final velocity of the body will be

  1. 30 m s-1
  2. 34 m s-1
  3. 40 m s-1
  4. 45 m s-1

B

Work Done Formula Quiz

MCQ: In the Earth's gravitational field with respect to the path followed, work done is

  1. dependent
  2. independent
  3. zero
  4. maximum

B

Angular and Linear Velocities Quiz

MCQ: First linear equation of motion is represented as

  1. Vi = Vf + at
  2. Vf = Vi - at
  3. Vf = Vi + at
  4. Vf = Vi + a

C