-1 Natural Numbers Integers Whole Numbers Rational Numbers
... of elements that belong to a set is called the cardinality of the set. Technically (and with a lot more mathematics behind you), it can be proven that the cardinality of the irrational numbers (uncountable infinity) is actually larger than the cardinality (size) of the rational numbers (countable in ...
... of elements that belong to a set is called the cardinality of the set. Technically (and with a lot more mathematics behind you), it can be proven that the cardinality of the irrational numbers (uncountable infinity) is actually larger than the cardinality (size) of the rational numbers (countable in ...
Exponential Notation Tutorial
... where a is a real number and the exponent, b is an integer. The number a is written in such a way that it is greater than 1 but less than 10. To find the value of b 1. For numbers > 1, count right to left the number of digitst up to but not including the leftmost one. Example: ...
... where a is a real number and the exponent, b is an integer. The number a is written in such a way that it is greater than 1 but less than 10. To find the value of b 1. For numbers > 1, count right to left the number of digitst up to but not including the leftmost one. Example: ...
PDF
... Although the theory Q is expressive enough to represent all computable functions and thus appears to be as strong as Peano Arithmetic, the fact that we removed the induction axiom will obviously have some effect on what is provable in Q. Here is one example. The formula (∀x)(x+16=x) is not valid in ...
... Although the theory Q is expressive enough to represent all computable functions and thus appears to be as strong as Peano Arithmetic, the fact that we removed the induction axiom will obviously have some effect on what is provable in Q. Here is one example. The formula (∀x)(x+16=x) is not valid in ...
How to solve inequalities and apply the distance formula
... How to solve inequalities and apply the distance formula Real Number System and Interval Notation: All the real numbers can be represented by points on a straight line (the real line). One distinguished point on the line represents the quantity 0, and a unit length is given so that k units from the ...
... How to solve inequalities and apply the distance formula Real Number System and Interval Notation: All the real numbers can be represented by points on a straight line (the real line). One distinguished point on the line represents the quantity 0, and a unit length is given so that k units from the ...
Notes
... All this started to go wrong when mathematicians “discovered” contradictory results about functions on the reals. Cauchy believed that all continuous functions were differentiable – until 1854 results of Riemann. In his Course on Analysis, Cauchy claimed that F (x) = ...
... All this started to go wrong when mathematicians “discovered” contradictory results about functions on the reals. Cauchy believed that all continuous functions were differentiable – until 1854 results of Riemann. In his Course on Analysis, Cauchy claimed that F (x) = ...
0.1 Numbers and Sets Real Numbers
... The _______________________of two sets A and B is the set of elements that are in either A or B. A ∪ B = { x | x ∈ A or x ∈ B}. The ____________________________of two sets A and B is the set of elements that are in both A and B. A ∩ B = { x | x ∈ A and x ∈ B}. ...
... The _______________________of two sets A and B is the set of elements that are in either A or B. A ∪ B = { x | x ∈ A or x ∈ B}. The ____________________________of two sets A and B is the set of elements that are in both A and B. A ∩ B = { x | x ∈ A and x ∈ B}. ...
Non-standard analysis
The history of calculus is fraught with philosophical debates about the meaning and logical validity of fluxions or infinitesimal numbers. The standard way to resolve these debates is to define the operations of calculus using epsilon–delta procedures rather than infinitesimals. Non-standard analysis instead reformulates the calculus using a logically rigorous notion of infinitesimal numbers.Non-standard analysis was originated in the early 1960s by the mathematician Abraham Robinson. He wrote:[...] the idea of infinitely small or infinitesimal quantities seems to appeal naturally to our intuition. At any rate, the use of infinitesimals was widespread during the formative stages of the Differential and Integral Calculus. As for the objection [...] that the distance between two distinct real numbers cannot be infinitely small, Gottfried Wilhelm Leibniz argued that the theory of infinitesimals implies the introduction of ideal numbers which might be infinitely small or infinitely large compared with the real numbers but which were to possess the same properties as the latterRobinson argued that this law of continuity of Leibniz's is a precursor of the transfer principle. Robinson continued:However, neither he nor his disciples and successors were able to give a rational development leading up to a system of this sort. As a result, the theory of infinitesimals gradually fell into disrepute and was replaced eventually by the classical theory of limits.Robinson continues:It is shown in this book that Leibniz's ideas can be fully vindicated and that they lead to a novel and fruitful approach to classical Analysis and to many other branches of mathematics. The key to our method is provided by the detailed analysis of the relation between mathematical languages and mathematical structures which lies at the bottom of contemporary model theory.In 1973, intuitionist Arend Heyting praised non-standard analysis as ""a standard model of important mathematical research"".