Consider the proposed matrix factorization: A = LS, where L is lower triangular with 1’s on...

A triangular matrix is called unit triangular if it is square and every main diagonal element...

A triangular matrix is called unit triangular if it is square and every main diagonal element is a 1. (a) If A can be carried by the gaussian algorithm to row-echelon form using no row interchanges, show that A = LU where L is unit lower triangular and U is upper triangular. (b) Show that the factorization in (a) is unique.

1. Consider the following production function: Y=F(A,L,K)=A(K^α)(L^(1-α)) where α < 1. a. Derive the Marginal Product...

1. Consider the following production function: Y=F(A,L,K)=A(K^α)(L^(1-α)) where α < 1. a. Derive the Marginal Product of Labor(MPL). b. Show that this production function exhibit diminishing MPL. c. Derive the Marginal Production of Technology (MPA). d. Does this production function exhibit diminishing MPA? Prove or disprove

Consider a function (fx) such that L(f)(2) = 1; f(0)=1; f'(0)=0 Where L(f)(s) denotes the Laplace...

Consider a function (fx) such that L(f)(2) = 1; f(0)=1; f'(0)=0 Where L(f)(s) denotes the Laplace transform of f(t) Calculate L(f'')(2)

Consider the Cobb-Douglas utility function u(x1,x2)=x1^(a)x2^(1-a). a. Find the Hicksian demand correspondence h(p, u) and the...

Consider the Cobb-Douglas utility function u(x1,x2)=x1^(a)x2^(1-a). a. Find the Hicksian demand correspondence h(p, u) and the expenditure function e(p,u) using the optimality conditions for the EMP. b. Derive the indirect utility function from the expenditure function using the relationship e(p,v(p,w)) =w. c. Derive the Walrasian demand correspondence from the Hicksian demand correspondence and the indirect utility function using the relationship x(p,w)=h(p,v(p,w)). d. vertify roy's identity. e. find the substitution matrix and the slutsky matrix, and vertify the slutsky equation. f....

Consider the Cobb-Douglas production function F (L, K) = (A)(L^α)(K^1/2) , where α > 0 and...

Consider the Cobb-Douglas production function F (L, K) = (A)(L^α)(K^1/2) , where α > 0 and A > 0. 1. The Cobb-Douglas function can be either increasing, decreasing or constant returns to scale depending on the values of the exponents on L and K. Prove your answers to the following three cases. (a) For what value(s) of α is F(L,K) decreasing returns to scale? (b) For what value(s) of α is F(L,K) increasing returns to scale? (c) For what value(s)...

Consider synthesis of poly(ethylene terephthalate) by polyesterification. Rate constants for polyesterification are 10-2 (L mol-1)2 s-1...

Consider synthesis of poly(ethylene terephthalate) by polyesterification. Rate constants for polyesterification are 10-2 (L mol-1)2 s-1 (no catalyst added) and 2x10-2 L mol-1s-1 (catalyst added). A) How long would it take to prepare a polyester of weight average molecular weight 3,000 under each set of conditions? Given that the initial dicarbixilic acid concentration is 3 mol L-1. B)If 5 mol% excess of diol were to be used in the previous problem, what number average molecular weight would be obtained if...

Consider the following production function: y = F(K, L, D) = TK^αL^β/D^α+β−1 where K, L and...

Consider the following production function: y = F(K, L, D) = TK^αL^β/D^α+β−1 where K, L and D represent capital, labor and land inputs respectively. Denote by s the capital-labor ratio (s = K L ). T captures technological progress and is assumed constant here. α and β are two parameters. (a) (2.5 marks) Does y exhibits constant returns to scale? Show your work. (b) (2.5 marks) Find the marginal product of capital (MPK), the marginal product of labor (MP L),...

Automata Theory and Formal Languages Problems 1: Consider the following two grammars. Grammar G1- S →...

Automata Theory and Formal Languages Problems 1: Consider the following two grammars. Grammar G1- S → aSb / ∈ Grammar G2- S → aAb / ∈, A → aAb / ∈ a. is G1=G2 b. What is the grammar generated by the expression Problem 2: Let us consider the grammar. G2 = ({S, A}, {a, b}, S, {S → aAb, aA → aaAb, A → ε } ) Derive aaabbb Problem 3: Suppose we have the following grammar. G: N...

Consider the differential equation y′′(t)+4y′(t)+5y(t)=74exp(−8t), with initial conditions y(0)=12, and y′(0)=−44. A)Find the Laplace transform of...

Consider the differential equation y′′(t)+4y′(t)+5y(t)=74exp(−8t), with initial conditions y(0)=12, and y′(0)=−44. A)Find the Laplace transform of the solution Y(s).Y(s). Write the solution as a single fraction in s. Y(s)= ______________ B) Find the partial fraction decomposition of Y(s). Enter all factors as first order terms in s, that is, all terms should be of the form (c/(s-p)), where c is a constant and the root p is a constant. Both c and p may be complex. Y(s)= ____ + ______...

Consider the balanced chemical reaction shown below. 1 Ca3P2(s) + 6 H2O(l) 3 Ca(OH)2(s) + 2...

Consider the balanced chemical reaction shown below. 1 Ca3P2(s) + 6 H2O(l) 3 Ca(OH)2(s) + 2 PH3(g) In a certain experiment, 3.981 g of Ca3P2(s) reacts with 4.412 g of H2O(l). (a) Which is the limiting reactant? (Example: type Ca3P2 for Ca3P2(s)) (b) How many grams of Ca(OH)2(s) form? (c) How many grams of PH3(g) form? (d) How many grams of the excess reactant remains after the limiting reactant is completely consumed?