Answer:
A) Alternative A has the lowest preak-even point at 3,572 units
B) Both alternatives A and B will produce the highest profit of $180,000.
C) 10,000 units between A and B
2,500 units between A and C
4,000 units between B and C
Explanation:
The revenue functions for each of the alternatives are:
[tex]R_A = (\$50-\$22)n - \$100,000\\R_B = (\$50-\$20)n - \$120,000\\R_C = (\$50-\$30)n - \$80,000[/tex]
Where 'n' is the annual output, in units produced.
A) At the break-even point, revenue is equal to zero. The break-even outputs for each alternative are:
[tex]0 = (\$50-\$22)n_A - \$100,000\\n_A = 3,572\\0 = (\$50-\$20)n_B - \$120,000\\n_B = 4,000\\0 = (\$50-\$30)n_C - \$80,000\\n_A = 4,000\\[/tex]
Alternative A has the lowest preak-even point at 3,572 units.
B) The revenues for each alternative at n=10,000 units are:
[tex]R_A = (\$50-\$22)10,000 - \$100,000\\R_A = \$180,000R_B = (\$50-\$20)10,000 - \$120,000\\R_B= \$180,000\\R_C = (\$50-\$30)10,000 - \$80,000\\R_C = \$120,000[/tex]
Both alternatives A and B will produce the highest profit of $180,000.
C) As seen above, for n=10,000 the company would be indifferent between A and B.
Between A and C:
[tex]R_A = R_C\\ (\$50-\$22)n - \$100,000 = (\$50-\$30)n - \$80,000\\n=\frac{100,000-80,000}{28-20} \\n=2,500[/tex]
Between B and C:
[tex]R_B = R_C\\ (\$50-\$20)n - \$120,000 = (\$50-\$30)n - \$80,000\\n=\frac{120,000-80,000}{30-20} \\n=4,000[/tex]
