definitions: 1.associativity of the conjunction 2. a subset of x

Here are two new definitions. Two schemata are compatible just in case their conjunction is satisfiable....

Here are two new definitions. Two schemata are compatible just in case their conjunction is satisfiable. Two schemata are congruent just in case their biconditional is satisfiable. Determine whether each of the generalizations below is true or false. If it is true, explain why it is true. If it is false, present a counterexample. (a) If two schemata X and Y are compatible, then they are congruent. (b) If two schemata are congruent, then they are compatible.

Consider a function F(x,y)=(1/y,x^2) find a subset that is regular (meaning it is 1-1, and continiously...

Consider a function F(x,y)=(1/y,x^2) find a subset that is regular (meaning it is 1-1, and continiously differentiable and JF(X,Y) is not equal to 0

Each of the following defines a metric space X which is a subset of R^2 with...

Each of the following defines a metric space X which is a subset of R^2 with the Euclidean metric, together with a subset E ⊂ X. For each, 1. Find all interior points of E, 2. Find all limit points of E, 3. Is E is open relative to X?, 4. E is closed relative to X? I don't worry about proofs just answers is fine! a) X = R^2, E = {(x,y) ∈R^2 : x^2 + y^2 = 1,...

Prove that if A is a subset of X, then a) A ∩ (X − A)...

Prove that if A is a subset of X, then a) A ∩ (X − A) = ∅. b) A ∪ (X − A) = X. c) X − (X − A) = A.

Let X be a subset of the integers from 1 to 1997 such that |X|≥34. Show...

Let X be a subset of the integers from 1 to 1997 such that |X|≥34. Show that there exists distinct a,b,c∈X and distinct x,y,z∈X such that a+b+c=x+y+z and {a,b,c}≠{x,y,z}.

(2) If K is a subset of (X,d), show that K is compact if and only...

(2) If K is a subset of (X,d), show that K is compact if and only if every cover of K by relatively open subsets of K has a finite subcover.

In this problem, we will explore how the cardinality of a subset S ⊆ X relates...

In this problem, we will explore how the cardinality of a subset S ⊆ X relates to the cardinality of a finite set X. (i) Explain why |S| ≤ |X| for every subset S ⊆ X when |X| = 1. (ii) Assume we know that if S ⊆ hni, then |S| ≤ n. Explain why we can show that if T ⊆ hn+ 1i, then |T| ≤ n + 1. (iii) Explain why parts (i) and (ii) imply that for...

Recall that a subset A (of N, Z, Q) is called downward closed when x ∈...

Recall that a subset A (of N, Z, Q) is called downward closed when x ∈ A and y < x implies y ∈ A. Suppose that A is a downward closed subset of Z, and consider the subsets B = {x + 1 ∈ Z | (∃y ∈ A).x2 ≤ y} C = {x − 1 ∈ Z | (∃y ∈ A).x < y2 } For each of B, C, determine whether it is downward closed in Z. Explain...

Give an example where X is not Hausdorff, and A is a compact subset of X,...

Give an example where X is not Hausdorff, and A is a compact subset of X, but A is not closed. Justify your claims with proof.

Suppose that X is complete. Show that a subset Y of X is complete if Y...

Suppose that X is complete. Show that a subset Y of X is complete if Y is closed