The problem is to maximise utility u(x, y) =2*x +y s.t. x,y ≥ 0 and p*x...

Maximise the utility u=5*ln(x-1)+ln(y-1) by choosing the consumption bundle (x,y) subject to the budget constraint x+y=10....

Maximise the utility u=5*ln(x-1)+ln(y-1) by choosing the consumption bundle (x,y) subject to the budget constraint x+y=10. Here, ln denotes the natural logarithm, * multiplication, / division, + addition, - subtraction. Ignore the nonnegativity constraints x,y>=0. Write the quantity x in the utility-maximising consumption bundle (x,y). Write the answer as a number in decimal notation with at least two digits after the decimal point. No fractions, spaces or other symbols.

Maximise square root utility Consumption of good 1 is denoted x_1 and consumption of good 2...

Maximise square root utility Consumption of good 1 is denoted x_1 and consumption of good 2 by x_2. The agent has the utility function u(x_1, x_2) = √x_1 + √x_2 (the square root of x_1 plus the square root of x_2). Here, √ denotes the square root, * multiplication, + addition. Maximize u by choosing (x_1,x_2) subject to the budget constraint x_1 +3*x_2<=12 and the minimal consumption amount constraints x_1>=0 and x_2>=3.35. Write the quantity x_1 of good 1 that...

The profit of a monopolist from producing quantities x,y and selling these in two markets with...

The profit of a monopolist from producing quantities x,y and selling these in two markets with linear demand curves is x*(9-x)+y*(1-y)-(x+y)^2. Here, ^ denotes power, * multiplication, / division, + addition, - subtraction. The monopolist chooses nonnegative quantities to maximise profit. Now one of these constraints binds. Find the quantity x that the monopolist sells in the first market. Write the answer as a number in decimal notation with at least two digits after the decimal point. No fractions, spaces...

The profit of a monopolist from producing quantities x,y and selling these in two markets with...

The profit of a monopolist from producing quantities x,y and selling these in two markets with linear demand curves is x*(10-x)+y*(9-y)-(x+y)^2. Here, ^ denotes power, * multiplication, / division, + addition, - subtraction. The monopolist chooses nonnegative quantities to maximise profit. Assume the nonnegativity constraints do not bind. Find the quantity x that the monopolist sells in the first market. Write the answer as a number in decimal notation with at least two digits after the decimal point. No fractions,...

The profit of a monopolist from producing quantities x,y and selling these in two markets with...

The profit of a monopolist from producing quantities x,y and selling these in two markets with linear demand curves is x*(10-x)+y*(9-y)-(x+y)^2. Here, ^ denotes power, * multiplication, / division, + addition, - subtraction. The monopolist chooses nonnegative quantities to maximise profit. Assume the nonnegativity constraints do not bind. Find the quantity x that the monopolist sells in the first market. Write the answer as a number in decimal notation with at least two digits after the decimal point. No fractions,...

Bordered Hessian element The Lagrangian is L=ln(x+y^2) -z^3/(3*y) -x*y +λ*(x*z +3*x^2*y -r), where r is a...

Bordered Hessian element The Lagrangian is L=ln(x+y^2) -z^3/(3*y) -x*y +λ*(x*z +3*x^2*y -r), where r is a parameter (a known real number). Here, ln denotes the natural logarithm, ^ power, * multiplication, / division, + addition, - subtraction. The border is at the top and left of the Hessian. The variables are ordered λ,x,y,z. Find the last element in the second row of the bordered Hessian at the point (λ,x,y,z) =(0.11, 0, 2440, 0.01167). This point need not be stationary and...

Maximising revenue subject to minimal profit A startup maximises revenue q*a from quantity q ≥ 0...

Maximising revenue subject to minimal profit A startup maximises revenue q*a from quantity q ≥ 0 and advertising a ≥ 0 subject to a bankruptcy constraint that the profit π = 3*q*a -q^3 -a^3 is greater than m=0.50. Here, ^ denotes power, * multiplication, / division, + addition, - subtraction. Find the total derivative of the maximised revenue w.r.t. the minimal required profit m at m=0.50. This derivative equals a Lagrange multiplier. Write the answer as a number in decimal...

Implicit derivative 1 Find y’(x) from F(x,y) =2^(-x -y) *ln(3*x +3*y) -x -y +(x+y)^3 =20 at...

Implicit derivative 1 Find y’(x) from F(x,y) =2^(-x -y) *ln(3*x +3*y) -x -y +(x+y)^3 =20 at (x,y)=(1, 1.824). Write y’(1) at this point as a number in decimal notation with at least two digits after the decimal point. No fractions, spaces or other symbols. Hint: the simple solution does not even require taking derivatives.

Social planner’s problem, two constraints 2 Five units of good 1 and five units of good...

Social planner’s problem, two constraints 2 Five units of good 1 and five units of good 2 are available. Consumption of good 1 is denoted x_1 and consumption of good 2 by x_2. There are two agents: A and B. Their utility functions are u_A(x_1, x_2) = ln(x_1) +a*ln(x_2) and u_B(x_1, x_2) = x_1 +b*x_2, where a=1.35 and b=0.86. Here, ln denotes the natural logarithm, * multiplication, + addition. Maximize u_A subject to the constraints u_B=1 and that each agent’s...

Social planner’s problem, two constraints 2 Five units of good 1 and five units of good...

Social planner’s problem, two constraints 2 Five units of good 1 and five units of good 2 are available. Consumption of good 1 is denoted x_1 and consumption of good 2 by x_2. There are two agents: A and B. Their utility functions are u_A(x_1, x_2) = ln(x_1) +a*ln(x_2) and u_B(x_1, x_2) = x_1 +b*x_2, where a=1.35 and b=0.86. Here, ln denotes the natural logarithm, * multiplication, + addition. Maximize u_A subject to the constraints u_B=1 and that each agent’s...