Bring the following logical proposition into a form where the quantifiers are in initial position: ¬(∃x∈X:∀y∈Y...

Bring the following logical proposition into a form where the quantifiers are in initial position: ∀z...

Bring the following logical proposition into a form where the quantifiers are in initial position: ∀z ∈ C : ∃t ∈ U : (∀q ∈ G(z,t) : W(q))∧(∃h ∈ H : J(t,h)) Write down its negation.

write the following sentences as quantified logical statements, using the universal and existential quantifiers, and defining...

write the following sentences as quantified logical statements, using the universal and existential quantifiers, and defining predicates as needed. Second, write the negations of each of these statements in the same way. Finally, choose one of these statements to prove. If it is true, prove it, and if it is false, prove its negation. Your proof need not use symbols, but can be a simple explanation in plain English. 1. If m and n are positive integers and mn is...

(1) Determine whether the propositions p → (q ∨ ¬r) and (p ∧ ¬q) → ¬r...

(1) Determine whether the propositions p → (q ∨ ¬r) and (p ∧ ¬q) → ¬r are logically equivalent using either a truth table or laws of logic. (2) Let A, B and C be sets. If a is the proposition “x ∈ A”, b is the proposition “x ∈ B” and c is the proposition “x ∈ C”, write down a proposition involving a, b and c that is logically equivalentto“x∈A∪(B−C)”. (3) Consider the statement ∀x∃y¬P(x,y). Write down a...

How to express the following statements using quantifiers and logical connectives? P(x): x has a car,...

How to express the following statements using quantifiers and logical connectives? P(x): x has a car, Q(x): x is rich, R(x): x is young, S(x): x can drive (a) Anyone has a car can drive. (b) No young people can drive. (c) Anyone rich has a car. (d) No young people are rich. (e) Does (3d) follow (3a), (3b) and (3c)? If not, is there a correct conclusion?

Consider the following (true) statement: “All birds have wings but some birds cannot fly.” Part 1...

Consider the following (true) statement: “All birds have wings but some birds cannot fly.” Part 1 Write this statement symbolically as a conjunction of two sub-statements, one of which is a conditional and the other is the negation of a conditional. Use three components (p, q, and r) and explicitly state what these components correspond to in the original statement. Hint: Any statement in the form "some X cannot Y" can be rewritten equivalently as “not all X can Y,”...

A Bernoulli differential equation is one of the form dy/dx+P(x)y=Q(x)y^n (∗) Observe that, if n=0 or...

A Bernoulli differential equation is one of the form dy/dx+P(x)y=Q(x)y^n (∗) Observe that, if n=0 or 1, the Bernoulli equation is linear. For other values of n, the substitution u=y^(1−n) transforms the Bernoulli equation into the linear equation du/dx+(1−n)P(x)u=(1−n)Q(x). Consider the initial value problem xy′+y=−8xy^2, y(1)=−1. (a) This differential equation can be written in the form (∗) with P(x)=_____, Q(x)=_____, and n=_____. (b) The substitution u=_____ will transform it into the linear equation du/dx+______u=_____. (c) Using the substitution in part...

Write logical expressions for the following conditions: x is not a negative number x is a...

Write logical expressions for the following conditions: x is not a negative number x is a multiple of 7 x is greater than the sum of y and z x is the greatest number among x, y, and z x is less than 99 but greater than 49

(1 point) A Bernoulli differential equation is one of the form dydx+P(x)y=Q(x)yn     (∗) Observe that, if n=0...

(1 point) A Bernoulli differential equation is one of the form dydx+P(x)y=Q(x)yn     (∗) Observe that, if n=0 or 1, the Bernoulli equation is linear. For other values of n, the substitution u=y1−n transforms the Bernoulli equation into the linear equation dudx+(1−n)P(x)u=(1−n)Q(x).dudx+(1−n)P(x)u=(1−n)Q(x). Consider the initial value problem y′=−y(1+9xy3),   y(0)=−3. (a) This differential equation can be written in the form (∗) with P(x)= , Q(x)= , and n=. (b) The substitution u= will transform it into the linear equation dudx+ u= . (c) Using...

Find an orthogonal matrix P such that a change of variables, x = Py, where x...

Find an orthogonal matrix P such that a change of variables, x = Py, where x = [x1, x2] , y = [y1, y2] , transforms the quadratic form 6x1^2+ 4x1x2 + 3x2^2 into one with no cross-product term. Write down the new quadratic form.

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

The problem is to maximise utility u(x, y) =2*x +y s.t. x,y ≥ 0 and p*x + q*y ≤ w, where p=13.4 and q=3.9 and w=1. Here, * denotes multiplication, / division, + addition, - subtraction. The solution to this problem is denoted (x_0, y_0) =(x(p, q, w), y(p, q, w)). The solution is the global max. Find ∂u(x_0,y_0)/∂p evaluated at the parameters (p, q, w) =(13.4, 3.9, 1). Write the answer as a number in decimal notation with at...