Determine if completeness and transitivity are satisfied for the following preferences defined on x = (x1,...

Determine if completeness and transitivity are satisfied for the following preferences defined on x = (x1,...

Determine if completeness and transitivity are satisfied for the following preferences defined on x = (x1, x2) and y = (y1, y2). (Hints: 1- You have to use z = (z1, z2) to prove or disprove transitivity. 2- You can disprove by a counter example) — x ≽y iff x1 > y1 or x1 = y1 and x2 > y2.

Determine if completeness and transitivity are satisfied for the following preferences defined on x = (x1,...

Determine if completeness and transitivity are satisfied for the following preferences defined on x = (x1, x2) and y = (y1, y2). (Hints: 1- You have to use z = (z1, z2) to prove or disprove transitivity. 2- You can disprove by a counter example) — x ≽y iff x1 > y1 or x1 = y1 and x2 > y2.

Determine if completeness and transitivity are satisfied for the following preferences defined on x = (x1,...

Determine if completeness and transitivity are satisfied for the following preferences defined on x = (x1, x2) and y = (y1, y2). x ≽ y iff x1 > y1 or x1 = y1 and x2 > y2. (Hints: 1- You have to use z = (z1, z2) to prove or disprove transitivity. 2- You can disprove by a counter example)

Consider a two-good economy c = (c1, c2) where the goods can only be consumed in...

Consider a two-good economy c = (c1, c2) where the goods can only be consumed in positive integer choices, that is c ∈ Z^2 and c ≥ 0. Consider the following three consumption bundles, x = (2,1), y = (α, 2), z = (2, β).. These are the only three consumption bundles Anne can choose from. Anne’s preferences are such that x ≻ y and y ≻ z, where “≻” means strict preference. Anne’s preferences are complete and satisfy transitivity...

Consider the set V = (x,y) x,y ∈ R with the following two operations: • Addition:...

Consider the set V = (x,y) x,y ∈ R with the following two operations: • Addition: (x1,y1)+(x2,y2)=(x1 +x2 +1, y1 +y2 +1) • Scalarmultiplication:a(x,y)=(ax+a−1, ay+a−1). Prove or disprove: With these operations, V is a vector space over R

Write vectors in R2 as (x,y). Define the relation on R2 by writing (x1,y1) ∼ (x2,y2)...

Write vectors in R2 as (x,y). Define the relation on R2 by writing (x1,y1) ∼ (x2,y2) iff y1 − sin x1 = y2 − sin x2 . Prove that ∼ is an equivalence relation. Find the classes [(0, 0)], [(2, π/2)] and draw them on the plane. Describe the sets which are the equivalence classes for this relation.

Let A = R x R, and let a relation S be defined as: “(x1 ,...

Let A = R x R, and let a relation S be defined as: “(x1 , y1 ) S (x2 , y2 ) ⬄ points (x1 , y1 ) and (x2 , y2 ) are 5 units apart.” Determine whether S is reflexive, symmetric, or transitive. If the answer is “yes,” give a justification (full proof is not needed); if the answer is “no” you must give a counterexample

4.4-JG1 Given the following joint density function in Example 4.4-1: fx,y(x,y)=(2/15)d(x-x1)d(y-y1)+(3/15)d(x-x2)d(y-y1)+(1/15)d(x-x2)d(y-y2)+(4/15)d(x-x1)d(y-y3) a) Determine fx(x|y=y1) Ans: 0.4d(x-x1)+0.6d(x-x2)...

4.4-JG1 Given the following joint density function in Example 4.4-1: fx,y(x,y)=(2/15)d(x-x1)d(y-y1)+(3/15)d(x-x2)d(y-y1)+(1/15)d(x-x2)d(y-y2)+(4/15)d(x-x1)d(y-y3) a) Determine fx(x|y=y1) Ans: 0.4d(x-x1)+0.6d(x-x2) b) Determine fx(x|y=y2) Ans: 1d(x-x2) c) Determine fy(y|x=x1) Ans: (1/3)d(y-y1)+(2/3)d(y-y3) d) Determine fx(y|x=x2) Ans: (3/9)d(y-y1)+(1/9)d(y-y2)+(5/9)d(y-y3) 4.4-JG2 Given fx,y(x,y)=2(1-xy) for 0 a) fx(x|y=0.5) (Point Conditioning) Ans: (4/3)(1-x/2) b) fx(x|0.5

N particles can move in plane (x,y). Write down coordinates and momenta of all particles forming...

N particles can move in plane (x,y). Write down coordinates and momenta of all particles forming the phase space and determine number of degrees of freedom s. (a) x1, px1, y1, py1, x2, px2, y2, py2,…, xN, pxN, yN, pyN , s=2N (b) x1, px1, x2, px2, …, xN, pxN , s=2N (c) y1, py1, y2, py2,…, yN, pyN , s=2N (d) x1, y1, x2, y2, …, xN, yN , s=2N and why you choose

Let there be two goods; coco puffs and grits. Assume that the preferences satisfy basic axioms...

Let there be two goods; coco puffs and grits. Assume that the preferences satisfy basic axioms and assumptions and they can be represented by the utility function u(x1,x2)= x1x2. Consider two bundles X= (1,20) and Y=(10,2). Which one do you prefer? Use bundles X and Y to illustrate that these tastes are in fact convex. What is the MRS at bundles X and Y respectively? Now consider tastes that are instead defined by the function u(x1,x2) = x1^2 + x2^2...