Rings and fields.
... common to denote the element ?((x, y)) as x ? y. An operation ? is: associative if for every x, y, z ∈ X x ? (y ? z) = (x ? y) ? z. commutative if for every x, y ∈ X x?y =y?x An element e ∈ X is called an identity for ? if for every x ∈ X e ? x = x ? e = x. Given an element x ∈ X, if there exists an ...
... common to denote the element ?((x, y)) as x ? y. An operation ? is: associative if for every x, y, z ∈ X x ? (y ? z) = (x ? y) ? z. commutative if for every x, y ∈ X x?y =y?x An element e ∈ X is called an identity for ? if for every x ∈ X e ? x = x ? e = x. Given an element x ∈ X, if there exists an ...
Algebra Workshop 1: Simple manipulation of expressions
... Vocabulary: Expanding a polynomial means to take whichever form it is currently in, and put it in the following form: an xn + an−1 xn−1 + an−2 xn−2 + ... + a0 Example: (x + 1)(x − 2) + 3 = x2 − 2x + x − 2 + 3 = x2 − x + 1. There, the largest value of n is 2, and a2 = 1, a1 = −1 and a0 = 1. Important ...
... Vocabulary: Expanding a polynomial means to take whichever form it is currently in, and put it in the following form: an xn + an−1 xn−1 + an−2 xn−2 + ... + a0 Example: (x + 1)(x − 2) + 3 = x2 − 2x + x − 2 + 3 = x2 − x + 1. There, the largest value of n is 2, and a2 = 1, a1 = −1 and a0 = 1. Important ...
A s
... Any component is either a directed path, all of whose vertices are in S’ besides the last one which is in U-S’, or a cycle, all of whose vertices are in S’. The crucial point now is that if there is an odd cycle in this subgraph, then the contribution of this term to det(B) is zero, as we can orient ...
... Any component is either a directed path, all of whose vertices are in S’ besides the last one which is in U-S’, or a cycle, all of whose vertices are in S’. The crucial point now is that if there is an odd cycle in this subgraph, then the contribution of this term to det(B) is zero, as we can orient ...
Some known results on polynomial factorization over towers of field
... Proposition 2. Consider ℓ < k, and suppose that f1 , . . . , fℓ are polynomials in K(t)[x] such that the following holds: 1. for i ≤ ℓ, fi is in K(t)[x1 , . . . , xi ], monic in xi and reduced with respect to (f1 , . . . , fi−1 ); 2. for i ≤ ℓ, fi is in D; 3. the ideal hf1 , . . . , fℓ i is maximal ...
... Proposition 2. Consider ℓ < k, and suppose that f1 , . . . , fℓ are polynomials in K(t)[x] such that the following holds: 1. for i ≤ ℓ, fi is in K(t)[x1 , . . . , xi ], monic in xi and reduced with respect to (f1 , . . . , fi−1 ); 2. for i ≤ ℓ, fi is in D; 3. the ideal hf1 , . . . , fℓ i is maximal ...
Algorithms for Manipulating Algebraic Functions
... for the coefficients. Operating with floating point numbers, it is nearly impossible to distinguish small non-zero numbers from a representation of zero with roundoff present. Related problems also occur when one use interval arithmetic. Several of the algorithms presented in this thesis provide a ...
... for the coefficients. Operating with floating point numbers, it is nearly impossible to distinguish small non-zero numbers from a representation of zero with roundoff present. Related problems also occur when one use interval arithmetic. Several of the algorithms presented in this thesis provide a ...
Math Circles - Number Theory
... Guess when an equation ax + by = c, with a, b, c in Z, has integer solutions x and y. Try to prove your conjecture. 3. Write out an inverse table for Z5 , Z6 , Z11 and Z12 . When do elements have an inverse? For which n is Zn a field? Prove both your assertions. 4. We know that sometimes we can choo ...
... Guess when an equation ax + by = c, with a, b, c in Z, has integer solutions x and y. Try to prove your conjecture. 3. Write out an inverse table for Z5 , Z6 , Z11 and Z12 . When do elements have an inverse? For which n is Zn a field? Prove both your assertions. 4. We know that sometimes we can choo ...
AQA Core 1 Polynomials Section 2: The factor
... You can use the factor theorem to solve cubic and higher order equations. These are the steps you need to take to solve a cubic equation of the form f(x) = 0, where f(x) is a cubic function: First, work out f(x) for different values of x until you find one for which f(x) = 0. Using the factor th ...
... You can use the factor theorem to solve cubic and higher order equations. These are the steps you need to take to solve a cubic equation of the form f(x) = 0, where f(x) is a cubic function: First, work out f(x) for different values of x until you find one for which f(x) = 0. Using the factor th ...
On the Sum of Square Roots of Polynomials and related problems
... Theorem 1.4 (Sum of square root of ‘polynomial integers’). Suppose S = i=1 δi ai (δi ∈ {+1, −1}) such that every positive integer ai is of the form ai = X di + bi1 · X di −1 + . . . + bidi (di > 0), where X is a positive real number and bij are integers. Let B = maxi,j {|bij |} and d = maxi {di }. I ...
... Theorem 1.4 (Sum of square root of ‘polynomial integers’). Suppose S = i=1 δi ai (δi ∈ {+1, −1}) such that every positive integer ai is of the form ai = X di + bi1 · X di −1 + . . . + bidi (di > 0), where X is a positive real number and bij are integers. Let B = maxi,j {|bij |} and d = maxi {di }. I ...
Brief Notes On Functions
... – Oblique Asymptote: An oblique or slant asymptote occurs when the degree of the numerator is exactly one greater than the degree of the denominator so that the end behavior of the function is a line. • Vertical Asymptotes: A vertical asymptote occurs at values of x where the denominator is equal to ...
... – Oblique Asymptote: An oblique or slant asymptote occurs when the degree of the numerator is exactly one greater than the degree of the denominator so that the end behavior of the function is a line. • Vertical Asymptotes: A vertical asymptote occurs at values of x where the denominator is equal to ...
Slide 1 - usd294.org
... • All rational roots will come from Factors of the last term / factors of the first term List the potential rational zeros of the polynomial function. F(x) = 3x5 – x2 + 2x + 18 Factors of the last term: +- 1,2,3,6,9,18 Factors of first term: 1,3 Possible rational roots: 1, 2, 3, 6, 9, 18, 1/3, 2/3, ...
... • All rational roots will come from Factors of the last term / factors of the first term List the potential rational zeros of the polynomial function. F(x) = 3x5 – x2 + 2x + 18 Factors of the last term: +- 1,2,3,6,9,18 Factors of first term: 1,3 Possible rational roots: 1, 2, 3, 6, 9, 18, 1/3, 2/3, ...
