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Describe the oscillation (complete an expression x(t) for that oscillation). An object being displaced on the frictionless table to the left from equilibrium position at distance 0.3 m while it moving to the left with a speed 0.6 m/s. Coefficient of spring 100 N/m, and mass of the block 50 g. Draw a diagram and complete all calculations: A) Calculate the amplitude of the oscillation B) What is the initial Phase of this oscillation C) What is the angular frequency D) Write the equation x(t) E) Evaluate your answers using a unit circle. Evaluate your solutions by drawing a unit circle diagram.

Describe the oscillation (complete an expression x(t) for that oscillation). An object being displaced on the frictionless table to the left from equilibrium position at distance 0.3 m while it moving to the left with a speed 0.6 m/s. Coefficient of spring 100 N/m, and mass of the block 50 g. Draw a diagram and complete all calculations: A) Calculate the amplitude of the oscillation B) What is the initial Phase of this oscillation C) What is the angular frequency D) Write the equation x(t) E) Evaluate your answers using a unit circle. Evaluate your solutions by drawing a unit circle diagram.

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Describe the oscillation (complete an expression x(t) for that oscillation). An object being displaced on the frictionless table to the left from equilibrium position at distance 0.3 m while it moving to the left with a speed 0.6 m/s. Coefficient of spring 100 N/m, and mass of the block 50 g. Draw a diagram and complete all calculations: A) Calculate the amplitude of the oscillation B) What is the initial Phase of this oscillation C) What is the angular frequency D) Write the equation x(t) E) Evaluate your answers using a unit circle. Evaluate your solutions by drawing a unit circle diagram.

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