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Find y2 for the following function:
y = log x + ax
Concept: undefined >> undefined
Find y2 for the following function:
x = a cosθ, y = a sinθ
Concept: undefined >> undefined
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If y = 500e7x + 600e-7x, then show that y2 – 49y = 0.
Concept: undefined >> undefined
If y = 2 + log x, then show that xy2 + y1 = 0.
Concept: undefined >> undefined
If = a cos mx + b sin mx, then show that y2 + m2y = 0.
Concept: undefined >> undefined
If y = `(x + sqrt(1 + x^2))^m`, then show that (1 + x2) y2 + xy1 – m2y = 0
Concept: undefined >> undefined
If y = sin(log x), then show that x2y2 + xy1 + y = 0.
Concept: undefined >> undefined
If xy . yx , then prove that `"dy"/"dx" = y/x((x log y - y)/(y log x - x))`
Concept: undefined >> undefined
If xy2 = 1, then prove that `2 "dy"/"dx" + y^3`= 0
Concept: undefined >> undefined
If y = tan x, then prove that y2 - 2yy1 = 0.
Concept: undefined >> undefined
If y = 2 sin x + 3 cos x, then show that y2 + y = 0.
Concept: undefined >> undefined
The following table gives the annual demand and unit price of 3 items.
| Items | Annual Demand (units) | Unit Price |
| A | 800 | 0.02 |
| B | 400 | 1.00 |
| C | 13,800 | 0.20 |
Ordering cost is ₹ 5 per order and holding cost is 10% of unit price. Determine the following:
- EOQ in units
- Minimum average cost
- EOQ in rupees
- EOQ in years of supply
- Number of orders per year
Concept: undefined >> undefined
A dealer has to supply his customer with 400 units of a product per week. The dealer gets the product from the manufacturer at a cost of ₹ 50 per unit. The cost of ordering from the manufacturers in ₹ 75 per order. The cost of holding inventory is 7.5 % per year of the product cost. Find
- EOQ
- Total optimum cost.
Concept: undefined >> undefined
A certain manufacturing concern has total cost function C = 15 + 9x - 6x2 + x3. Find x, when the total cost is minimum.
Concept: undefined >> undefined
By the principle of mathematical induction, prove the following:
13 + 23 + 33 + ….. + n3 = `("n"^2("n + 1")^2)/4` for all x ∈ N.
Concept: undefined >> undefined
By the principle of mathematical induction, prove the following:
1.2 + 2.3 + 3.4 + … + n(n + 1) = `(n(n + 1)(n + 2))/3` for all n ∈ N.
Concept: undefined >> undefined
By the principle of mathematical induction, prove the following:
4 + 8 + 12 + ……. + 4n = 2n(n + 1), for all n ∈ N.
Concept: undefined >> undefined
By the principle of mathematical induction, prove the following:
1 + 4 + 7 + ……. + (3n – 2) = `("n"(3"n" - 1))/2` for all n ∈ N.
Concept: undefined >> undefined
By the principle of mathematical induction, prove the following:
32n – 1 is divisible by 8, for all n ∈ N.
Concept: undefined >> undefined
By the principle of mathematical induction, prove the following:
an – bn is divisible by a – b, for all n ∈ N.
Concept: undefined >> undefined
