The solution to a problem is the equation below. Which description best fits this solution? 1 500 (0.120 m) - (2.00 kg) 9.80 (0.120 m) +(2.00 kg) 9.80 029 0 m) (2.00 824 A A vertical spring compressed 0.120 m shoots a 2.00-kg mass 2.90 cm above the equilibrium position of the spring. B A vertical spring stretched 0.120 m shoots a 2.00-kg mass 9.10 cm above the equilibrium position of the spring. A vertical spring compressed 0.120 m shoots a 2.00-kg mass 12.0 cm above the equilibrium position of the spring. A vertical spring compressed 0.120 m shoots a 2.00-kg mass 14.9 cm above the equilibrium position of the spring. A 2.00-kg mass has fallen 0.820 m and compressed the upper end of a vertical spring 12.0 cm below the equilibrium E position.

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The solution to a problem is the equation below. Which description best fits this solution? 1 500 N (0.120 m)? - (2.00 kg) 9.80- 20 m) m -00 ka 0.824 +2.0 ka) 9.80 .029 0 m) + (2.00 kg) 9.80- (0.0290 m) A A vertical spring compressed 0.120 m shoots a 2.00-kg mass 2.90 cm above the equilibrium position of the spring. (B A vertical spring stretched 0.120 m shoots a 2.00-kg mass 9.10 cm above the equilibrium position of the spring. A vertical spring compressed 0.120 m shoots a 2.00-kg mass 12.0 cm above the equilibrium position of the spring. DA vertical spring compressed 0.120 m shoots a 2.00-kg mass 14.9 cm above the equilibrium position of the spring. A 2.00-kg mass has fallen 0.820 m and compressed the upper end of a vertical spring 12.0 cm below the equilibrium (E position.