Sunday 15 May 2016

our blog created for always best result for others.
Give queries for better result.join this site.
Click here

Tuesday 10 May 2016

What is function

What Are Functions?

Functions are what we use to describe things we want to talk about mathematically. I find, though, that I get a bit tongue tied when I try to define them.
The simplest definition is: a function is a bunch of ordered pairs of things (in our case the things will be numbers, but they can be otherwise), with the property that the first members of the pairs are all different from one another.
Thus, here is an example of a function:
[{1, 1}, {2, 1}, {3, 2}]
This function consists of three pairs, whose first members are 1, 2 and 3.
It is customary to give functions names, like f, g or h, and if we call this function f, we generally use the following notation to describe it:
f(1) = 1, f(2) = 1, f(3) = 2
The first members of the pairs are called arguments and the whole set of them is called the domain of the function. Thus the arguments of f here are 1, 2 and 3, and the set consisting of these three numbers is its domain.
The second members of the pairs are called the values of the functions, and the set of these is called the range of the function.
The standard terminology for describing this function f is:
The value of f at argument 1 is 1, its value at argument 2 is 1, and its value at argument 3 is 2, which we write as f(1) = 1, f(2) = 1, f(3) = 2.
We generally think of a function as a set of assignments of values (second members of our pairs) to arguments (their first members).
The condition that the first members of the pairs are all different is the condition that each argument in the domain of f is assigned aunique value in its range by any function.
Above Consider the function g, defined by the pairs (1, 1), (2, 5), (3, 1) and (4, 2). What is its domain? What is the value of g at argument 3? What is g(4)?
If you stick a thermometer in your mouth, you can measure your temperature, at some particular time. You can define a function T or temperature, which assigns the temperature you measure to the time at which you remove the thermometer from your mouth. This is a typical function. Its arguments are times of measurement and its values are temperatures.
Of course your mouth has a temperature even when you don't measure it, and it has one at every instant of time and there are an infinite number of such instants.
This means that if you want to describe a function T whose value at any time t is the temperatures in your mouth at that time, you cannot really list all its pairs. There are an infinite number of possible arguments t and it would take you forever to list them.
Instead, we employ a trick to describe a function f: we generally provide a rule which allows you, the reader, to choose any argument you like in f's domain, and, by using the rule, to compute the value of your function at that argument. This rule is often called a formula for the function. The symbol x is often used to denote the argument you will select, and the formula tells you how to compute the function at that argument.
The simplest function of all, sometimes called the identity function, is the one that assigns as value the argument itself. If we denote this function as f, it obeys
f(x) = x
for x in whatever domain we choose for it. In other words, both members of its pairs are the same wherever you choose to define it.
We can get more complicated functions by giving more complicated rules, (These rules are often called formulae as we have noted already). Thus we can define functions by giving any of the following formulae among an infinity of possibilities:
These represent, respectively, 3 times x, x squared, 3 divided by x, x divided by the sum of the square of x and 1, and so on.
We can construct functions by applying the operations of addition, subtraction, multiplication and division to copies of x and numbers in any way we see fit to do so.
There are two very nice features of functions that we construct in this way, and the first applies to all functions.
We can draw a picture of a function, called its graph on a piece of graph paper, or on a spreadsheet chart or with a graphing calculator. We can do it by taking argument-value pairs of the function and describing each by a point in the plane, with x coordinate given by the argument and y coordinate given by the value for that pair.
Of course it is impossible to plot all the pairs of a function, but we can get a pretty good idea of what its graph looks like by taking perhaps a hundred evenly spaced points in any interval of interest to us. This sounds like an impossibly tedious thing to do and it used to be so, but now it is not. On a spreadsheet, the main job is to enter the function once (with its argument given by the address of some other location). That and some copying is all you have to do, and with practice it can be done in 30 seconds for a very wide variety of functions.
The second nice feature is that we can enter any function formed by adding, subtracting, multiplying, dividing and performing still another operation, on the contents of some address very easily on a spreadsheet or graphing calculator. Not only that, these devices have some other built in functions that we can use as well.
The two of these facts mean that we can actually look at any function formed by adding subtracting multiplying or dividing copies of the identity function x and other built in functions, and any number we want, and see how they behave, with very limited effort.
We will soon see that we can use the same procedure used for constructing functions to construct their derivatives as well, but that is getting ahead of the story. We can compute derivatives for most functions numerically with only a small amount of effort as well.

Ref From math.MIT.edu


Friday 6 May 2016

Bionomial expansion

Binomial Theorem
For some basic values:


Binomial Expansion

For any power of n, the binomial (a + x) can be expanded


This is particularly useful when x is very much less than a so that the first few terms provide a good approximation of the value of the expression. There will always be n+1 terms and the general form is:

Some basic properties
Funda: There is one more term than the power of the
exponent, n. That is, there are terms in the expansion
of (a + b)n
.
Funda: In each term, the sum of the exponents is n,
the power to which the binomial is raised.
Funda: The exponents of a start with n, the power of
the binomial, and decrease to 0. The last term has no
factor of a. The first term has no factor of b, so
powers of b start with 0 and increase to n.
Funda: The coefficients start at 1 and increase
through certain values about “half”-way and then
decrease through these same values back to 1.
Funda: To find the remainder when (x + y)n
is divided
by x, find the remainder when yn
is divided by x.
Funda: (1+x)n ≅ 1 + nx,

When binomial expressions are expanded, is there any type of pattern developing which might help us expand more quickly?  Consider the following expansions:

What observations can we make in general about the expansion of (a + b)n ?

1. The expansion is a series (an adding of terms).
2.The number of terms in each expansion is one more than n.  (terms = n + 1)
3.The power of starts with an and decreases by one in each successive term ending with a0.  The power of bstarts with b0 and  increases by one in each successive term ending with bn.
4.The power of b is always one less than the "number" of the term.  The power of a is always n minus the power of b.
5. The sum of the exponents in each term adds up to n. 
6.The coefficients of the first and last terms are each one.
7. 
The coefficients of the middle terms form an interesting (but perhaps not easily recognized) pattern where each coefficient can be determined from the previous term.  The coefficient is the product of the previous term's coefficient and a's index, divided by the number of that previous term.
         Check it out:  
The second term's coefficient is determined by a4
The third term's coefficient is determined by 4a3b
To Get Coefficient
From the Previous Term:
(This pattern will eventually be expressed as a combination of the form n C k..)
8.Another famous pattern is also developing regarding the coefficients.  If the coefficients are "pulled off" of the terms and arranged, they form a triangle known as Pascal's triangle.  (The use of Pascal's triangle to determine coefficients can become tedious when the expansion is to a large power.)
1
1    1
1    2    1
1    3    3    1
1     4    6     4    1
(notice the symmetry of the triangle)
 
(The two outside edges of the triangle are comprised of ones.  The other terms are each the sum of the two terms immediately above them in the triangle.)

By pulling these observations together with some mathematical syntax, a theorem is formed relating to the expansion of binomial terms:
Binomial Theorem(or Binomial Expansion Theorem)
Most of the syntax used in this theorem should look familiar. The notation is just another way of writing a combination such as n C k  (read "n choose k").

(Ref from wild math) 
Our pattern to obtain the coefficient using the previous term (in observation #6), actually leads to the n C k used in the binomial theorem.
Here is the connection.  Using our coefficient pattern in a general setting, we get:

Let's examine the coefficient of the fourth term, the one in the box.
If we write a combination 
n C  using k = 3, (for the previous term), we see the connection:


The Binomial Theorem can also be written in its expanded form as:

Remember that 
 and that 
Examples using the Binomial Theorem:
1.  Expand  .
Let a = x, b = 2, = 5 and substitute.  (Do not substitute a value for k.)
    




Ref from (purplemaths,regentspre.org)

Foundation of maths

Introduction to the foundations of mathematics

Mathematics and theories

Mathematics is the study of systems of elementary objects, whose only nature is to be exact, unambiguous (two objects are equal or different, related or not; an operation gives an exact result...). Such systems are conceived independently of our usual world, even if many of them can resemble (thus be used to describe) diverse aspects of it. Mathematics as a whole can be seen as «the science of all possible worlds» of this kind (of exact objects). 
Mathematics is split into diverse branches, implicit or explicit frameworks of any mathematical work, that may be formalized as (axiomatic) theories. Each theory is the study of a supposedly fixed system (world) of objects, called its model. But each model of a theory may be just one of its possible interpretations, among other equally legitimate models. For example, roughly speaking, all sheets of paper are systems of material points, models of the same theory of Euclidean plane geometry, but independent of each other.

Foundations and developments

Each theory starts with a foundation, that is the data of a list of pieces of description specifying what it knows or assumes of its model(s) (its kind or shape). This includes a list of formulas (statements) called axioms, expressing the required properties of models, i.e. selecting its accepted models as the systems where the axioms are true, from the whole range of possible systems where they can be interpreted. 
Then, the study of a theory progresses by choosing some of its possible developments : new concepts and information about its models, resulting from its given foundation, and that we can add to it to form its next foundation.
In particular, a theorem of a theory, is a formula deduced from its axioms, so that it is known as true in all its models. Theorems can be added to the list of axioms of a theory without modifying its meaning.
Other possible developments (not yet chosen) can still be operated later, as the part of the foundation that could generate them is preserved. Thus, the totality of possible developments of a theory, independent of the order chosen to process them, already forms a kind of «reality» that these developments explore (before the Completeness theorem will finally show how the range of possible theorems precisely reflects the more interesting reality of the diversity of possible models).
There are possible hierarchies between theories, where some can play a foundational role for others. For instance, the foundations of several theories may have a common part forming a simpler theory, whose developments are applicable to all.
A fundamental work is to develop, from a simple initial basis, a more complete foundation endowed with efficient tools opening more direct ways to further interesting developments.

The cycle of foundations

Despite the simplicity of nature of mathematical objects, the general foundation of all mathematics turns out to be quite complex (though not as bad as a physics theory of everything). Indeed, it is itself a mathematical study, thus a branch of mathematics, calledmathematical logic. Like any other branch, it is made of definitions and theorems about systems of objects. But as its object is the general form of theories and systems they may describe, it provides the general framework of all branches of mathematics... including itself.
And to provide the framework or foundation of each considered foundation (unlike ordinary mathematical works that go forward from an assumed foundation), it does not look like a precise starting point, but a sort of wide cycle composed of easier and harder steps. Still this cycle of foundations truly plays a foundational role for mathematics, providing rigorous frameworks and many useful concepts to diverse branches of mathematics (tools, inspirations and answers to diverse philosophical questions).
(This is similar to dictionaries defining each word by other words, or to another science of finite systems: computer programming. Indeed computers can be simply used, knowing what you do but not why it works; their working is based on software that was written in some language, then compiled by other software, and on the hardware and processor whose design and production were computer assisted. And this is much better than at the birth of this field.) 
It is dominated by two theories:
  • Set theory describes the universe of «all mathematical objects», from the simplest to the most complex such as infinite systems (in a finite language). It can roughly be seen as one theory, but in details it will have an unlimited diversity of possible variants (not always equivalent to each other).
  • Model theory is the general theory of theories (describing their formalisms as systems of symbols), and their possible models.
Each one is the natural framework to formalize the other: each set theory is formalized as a theory described by model theory; the latter better comes as a development from set theory (defining theories and systems as complex objects) than directly as a theory. Both connections must be considered separately: both roles of set theory, as a basis and an object of study for model theory, must be distinguished. But these formalizations will take a long work to complete, especially for this following last piece:
  • Proof theory completes model theory by describing a possible formal system of rules of proofs giving the theorems of any theory. A theory is consistent if its theorems will never contradict each other. Inconsistent theories cannot have any model, as the same statement cannot be true and false on the same system.
Model theory and proof theory are essentially unique, giving a clear natural meaning to the concepts of theory, theorems and consistency of each theory. 
From settheory.net
If u like this plz give us query and follow ....

Set theory

Set theory


The set theory was developed by George Cantor in 1845-1918. Today, it is used in almost every branch of mathematics and serves as a fundamental part of present-day mathematics.
In set theory we will learn about representation in roster form and set builder form , types of sets (Empty set, singleton set, finite and infinite sets, equal and equivalent sets), cardinal number of a set, subsets (Proper subset, super set, power set), number of proper subsets, universal set, operation on sets (Union, intersection, difference and complement of sets).

In everyday life, we often talk of the collection of objects such as a bunch of keys, flock of birds, pack of cards, etc. In mathematics, we come across collections like natural numbers, whole numbers, prime and composite numbers. 
(Ref Britannia. Math)

Let us examine the following collections:

1 Even natural numbers less than 20, i.e., 2, 4, 6, 8, 10, 12, 14, 16, 18. 

2Vowels in the English alphabet, i.e., a, e, i, o, u. 

3 Prime factors of 30 i.e. 2, 3, 5. 

4Triangles on the basis of sides, i.e., equilateral, isosceles and scalene. 

We observe that these examples are well-defined collections of objects.

Let us examine some more collections. 

1 five most renowned scientists of the world. 

2 Seven most beautiful girls in a society. 

3 Three best surgeons in America. 

These examples are not well-defined collections of objects because the criterion for determining as most renowned, most beautiful, best, varies from person to person. 

Sets:
A set is a well-defined collection of distinct objects.

We assume that,

 The word set is synonymous with the word collection, aggregate, class and comprises of elements.

 Objects, elements and members of a set are synonymous terms.

 Sets are usually denoted by capital letters A, B, C, ....., etc.

 Elements of the set are represented by small letters a, b, c, ....., etc.

If ‘a’ is an element of set A, then we say that ‘a’ belongs to A. We denote the phrase ‘belongs to’ by the Greek symbol ‘∈‘ (epsilon). Thus, we say that a ∈ A.

If ‘b’ is an element which does not belong to A, we represent this as b ∉ A.
Some important sets used in mathematics are

N: the set of all natural numbers = {1, 2, 3, 4, .....}

Z: the set of all integers = {....., -3, -2, -1, 0, 1, 2, 3, .....}

Q: the set of all rational numbers

R: the set of all real numbers

Z+: the set of all positive integers

W: the set of all whole numbers

In other words


  1. the branch of mathematics which deals with the formal properties of sets as units (without regard to the nature of their individual constituents) and the expression of other branches of mathematics in terms of sets.
Concept of set theory:- 
set theorybranch of mathematics that deals with the properties of well-defined collections of objects, which may or may not be of a mathematical nature, such as numbers or functions. The theory is less valuable in direct application to ordinary experience than as a basis for precise and adaptable terminology for the defination of complex and sophisticated mathematical concepts.

Between the years 1874 and 1897, the German mathematician and logician Georg Cantor created a theory of abstract sets of entities and made it into a mathematical discipline. This theory grew out of his investigations of some concrete problems regarding certain types of infinite sets of real numbers. A set wrote Cantor, is a collection of definite, distinguishable objects of perception or thought conceived as a whole. The objects are called elements  or members of the set.
The theory had the revolutionary aspect of treating infinite sets as mathematical objects that are on an equal footing with those that can be constructed in a finite number of steps. Since antiquity, a majority of mathematicians had carefully avoided the introduction into their arguments of the actual infinite (i.e., of sets containing an infinite of objects conceived as existing simultaneously, at least in thought). Since this attitude persisted until almost the end of the 19th century, Cantor’s work was the subject of much criticism to the effect that it dealt with fictions—indeed, that it encroached on the domain of philosophers and violated the principles of religion. Once applications to analysis began to be found, however, attitudes began to change, and by the 1890s Cantor’s ideas and results were gaining acceptance. By 1900, set theory was recognized as a distinct branch of mathematics.
At just that time, however, several contradictions in so-called naive set theory were discovered. In order to eliminate such problems, an axiomatic basis was developed for the theory of sets analogous to that developed for elementary geometry. The degree of success that has been achieved in this development, as well as the present stature of set theory, has been well expressed in the Nicolas baurbakis (begun 1939; “Elements of Mathematics”): “Nowadays it is known to be possible, logically speaking, to derive practically the whole of known mathematics from a single source, The Theory of Sets.”

Continue...


If u like this please give us query and follow.....