When returns from a project can be assumed to be normally distributed, such as those shown in Figure 13-6 (represented by a symmetrical, bell-shaped curve), the areas under the curve can be determined from statistical tables based on standard deviations. For example, 68.26 percent of the distribution will fall within one standard deviation of the expected value ( D + 10). Similarly, 95.44 percent will fall within two standard deviations ( D + 20), and so on. An abbreviated table of areas under the normal curve is shown next. Number of o's From Expected Value 0.50 1.00 1.se 2.39 2.74 + or 0.1915 0.3413 0.4332 0.4916 0.4969 + and 0.3830 0.6826 0.8664 0.9832 0.9938 Assume Project A has an expected value of $31,000 and a standard deviation () of $6,200. e. What is the probabilityIthat the outcome will be less than $27.900 or greater than $34,100? (Round your answer to 4 decimal places.) Probability When returns from a project can be assumed to be normally distributed, such as those shown in Figure 13-6 (represented by a symmetrical, bell-shaped curve), the areas under the curve can be determined from statistical tables based on standard deviations. For example, 68.26 percent of the distribution will fall within one standard deviation of the expected value ( D + 10). Similarly, 95.44 percent will fall within two standard deviations ( D + 20), and so on. An abbreviated table of areas under the normal curve is shown next. Number of o's From Expected Value 0.50 1.00 1.se 2.39 2.74 + or 0.1915 0.3413 0.4332 0.4916 0.4969 + and 0.3830 0.6826 0.8664 0.9832 0.9938 Assume Project A has an expected value of $31,000 and a standard deviation () of $6,200. e. What is the probabilityIthat the outcome will be less than $27.900 or greater than $34,100? (Round your answer to 4 decimal places.) Probability