Friday, December 16, 2011

An Example of a Novel Way to Understand Math in Real World - Financial Mathematics

You can download all the important posts as  PDF book "Unlocking the Secrets of Quantitative Thinking".

Probably every 7th grader will be able to do the following mathematical tasks.

Let ‘s assume we are given the following numbers

            1,000,000        1,435,900        1,500,000        1,400,000       

Pair the numbers 1,000,000 and 1,435,900, like this:
           
            (1,000,000 ,  1,435,900)          Pairing done.

Subtract  1.435.900 from 1,500,000 and show the result:

            1,500,000 – 1.435,900 = 64, 100         Subtraction done.
           
            64,100                                                 Result shown.

Subtract 1,435,900 from 1,400,000 and show the result:

            1,400,000 – 1,435,900 = - 35,900      Subtraction done.

            -35,900                                                Result shown.

Would you be surprised that this is mathematics that is thought in undergraduate studies in quantitative finance? Now, of course, that’s not the whole story, because there are other more exotic parts of mathematics that are taught as well, even within the same course. Those other parts are probability, statistics, and stochastic calculus, for instance. Yet, it’s amazing that this simple calculations are found in very important illustrations of some central financial concepts.

So, where is the trouble? Why not teach 7th grader quantitative finance and financial mathematics, since the student already has required mathematical knowledge? As a matter of fact, it is possible. Why it is not done is a different story. A few wrong turns in math education and you are lost in numerical labyrinth for the rest of your career. I want to rectify that.

Here is the actual explanation where these numbers come from. The following is the excerpt from an excellent, extraordinary book (“Options, Futures, and Other Derivatives”, 5th edition, John C. Hull)  in which the definition of a forward contract and certain trading technique associated with it are defined.


While mathematicians are satisfied with the starting, almost innocent phrase ”Let’s assume", "we are given", or "suppose”, and start writing numbers on paper a-priori, without any explanation, directly from fundamental axioms (be it ZFC or Peanno), a financial specialist must deal with, has to strictly define logic and provide reasoning where and why these numbers came into consideration. It is not enough to say that “we assume”, or, “the numbers are given”. Why are they given? Who gave them? Where from?

What a mess of descriptions. For instance, payoff  from forward contract. It is only one of many non mathematical concepts, concepts extraneous to mathematical world, concepts never used in the proofs of mathematical theorems. The others are buy, sell, outcome, position, forward contract, trade, bank, treasury! One has to know these definitions, their relationships, logic that applies to them way before even considering to enter number handling generated by these concepts. Postponing the introduction of the role of proof in mathematics teachers may further blur the boundary between pure and applied math.

Payoff appears to be the word of the day! It specifies a numerical procedure to be performed on selected numbers. Also, legal terms are thrown into the payoff and forward contract definition mix as well, like corporations is legally bind, it's obliged to keep its part of the contract, be it buy, or sell the asset. Obliged is an additional property to buy GBP 1,000,000 for $1,435,900. Note how these properties are added as flavours to the numbers 1,000,000 and 1,435,9000. Math here is very simple. two numbers are given! That's it! But, what is behind the definition of "given" is very important in finance.  From mathematical point of view ( i.e from setology point of view) the numbers' existence is guaranteed by fundamental axioms. No explanation necessary. All those classification, including different currency, who owns the currency, who buys and who sells, is outside math! So, these two numbers are linked together through some kind of specific financial logic, which has its own vocabulary and conceptual relationships. Mathematically, it's sufficient to pair these two numbers, like this:

(1 000 000,  1 435 900 )

What is attached to this pair of numbers is the reasoning why we paired them,  and the financial definitions extraneous to mathematical world. It's the world of financial concepts and relationships, and they do not belong to math.

As we continue reading about this forward contract trade, we come to the concept of "spot exchange rate". This is another "number generator" or "number picker". Now, we have a triplet of selected numbers, with the exchange rate definition in the background:

(1 000 000, 1 435 900, 1 500 000)

From math point of view, the number 1,500,000 is added arbitrary, i.e. math does not see the reason where and why this number is coming from. It's given. We suppose it. It's assumed is there. How we can ignore the fact of spot price presence, exchange rate, etc? Because in order to subtract these numbers, the mentioned definitions are irrelevant for the subtraction. Hence, the words "It's given..." immediately isolate pure math operations and numbers from the set descriptions(of sets they belong to) and from the objects definitions they represent count of. Notice how the words "Let's suppose" can blatantly keep you in dark about, sometimes, beautiful logic inisde the field math is applied to, and how it can suck out any pleasure in working with applied mathematics.

Then, there comes the question "how much is forward contract worth?". This particular question dictates which numbers will be picked and which math operations will be performed on them. 

Again, from mathematics point of view, it is specified, without any further explanation, which numbers are in game. For math, it is enough to use word “IF” and start generating numbers and their relationships. This “IF” implies usage of fundamental axioms. Hence, IF you have number 1,500,000 and IF you have number 1,435,000, deduct the second number from the first. That’s what matters to mathematics. To finance, the reasoning why you deduct second number from the first (and not vice versa).

Payoff = ST – K

Who would expect that the number 1,435,000 will have the following description: it is a six months forward offer quote for USD-GDP currency exchange. Note how this definition has almost nothing mathematical in itself (except number six, for six months). Cardinalities of a set are not part of this definition. You have to know all this just to pick one number! And that knowledge matters. If your non mathematical logic is flawed, you will select a wrong starting number and, even if your subsequent mathematical operations are perfectly accurate, the result will make no sense within the applied field, because the initial number was wrong.

Educators can ask math students the following question: "Give me an example what number 1,435,900 can represent count of". And, student will start searching from his or her experiences what can have that count. it can be 1,435,900 apples, 1,435,900 pears, 1,435,900 oranges, 1,435,900 birds, 1,435,900 rockets, even 1,435,900 thoughts. But, would you expect from a student to give you the following interpretation: "Number 1,435,900 is the number of dollars a bank is offering in a 6-months forward contract, in currency exchange for 1,000,000 British pounds on August 16, 2001" ? Probably not. You don't expect student to know financial concepts at that early age. And, moreover, why would the financial field should be in focus for this example. So, what is the point of asking student to give you example of a number, unless you want to indicate that there have to exist World # 1, in this case financial world, that has its own set of rules, axioms, premises, definitions, whose logic will define to which set the number 1,435,900 belongs? This financially based description apparently can not be deduced by looking at the number only. And, that there is World # 2, world of pure math, which starts with "given" numbers, no matter what is the reasoning of obtaining that number. Distinguishing these two worlds is in the essence of understanding mathematics.

Look at the freedom of how the scenarios in this trade are created: if spot rate falls to 1,400,000. Note the "number picker"! It's "spot rate"! Look how the fundamental axiom that number exist, is disguised in this functional description why and what picks actual number. From math point of view, this is the same as "number is given", 'let's suppose", "let's assume".

The interplay between pure math and our numbers is further advanced with actual logic between numbers' sources. While the sources themselves do not belong to math world, the numbers picked by them do. Hence, the rules between these "sources" (which are extraneous to mathematics) indirectly influence which numbers will be picked and will enter the specified calculation. Also note that the actual math operation is motivated by the things and reasoning outside math. We want to do subtraction because we want to find the payoff! Payoff, as a concept, has nothing to do with math. If it does you will see theorems in mathematics proved using or referencing this concept. But there are no such theorems. So, we have payoff as:

Payoff = 1,400,00 - 1,435,900 = -35,900

So, here, you deal with specifications what each number represents, and financial logic and reasoning structures what to do, what sequence of mathematical operations to perform. Whether the result of this calculation is called "payoff" or "orange with freckles" or "space carrot", mathematics couldn't care less. Math sees only two numbers provided to it and math operation to do. It's up to you to keep track what is counted and why.

In financial application of mathematics, we want to generalize the math operations on specific numbers, using, apparently the English language and financial terms and definitions from the financial domain of counting.  Hence, we will say, the payoff from a long position in a forward contract on one unit of asset is:

ST – K

Look how we have described the logic and requirements what to do with numbers. This reasoning is completely outside mathematics, and the sequence in subtraction matters to the financial domain. Math just see the numbers and subtraction. What these numbers represent, i.e. which set they belong to, is described in financial terms. We have ST = spot price and K = forward contractually specified price. The pairing of these numbers, before even any mathematical operation is done on them (in this case it is subtraction), is specified by the definition of a forward contract, by existence and definition of market, concept of spot trading. This is what is required for you to know to pick right cardinalities at the first place, before doing any mathematical operations on them.

You have a number, say, 1,500,000. Pure number. Units are not yet assigned to it. The number will remain the same, but the definition what it represents will change in accordance to some domain rules. In finance, these rules are defined by "buy" "sell" "obliged" "exchange" "asset" "forward" "payoff". These definitions and rules change the ownership of that cardinality, that number. Note how number, and for that matter quantity of dollars it represents, remains unchanged. What is changed is who owns that amount of currency, and that's not a mathematical concept.

It is a "fierce pairing of numbers" and "fierce changing" of descriptions of sets to which those (same!) numbers belong to which is part of the forward definition and many aspects of trading. The similar conclusion applies to other domains of applied mathematics.

You can download this post as an article in PDF File format by clicking the picture below.



[ applied mathematics, financial mathematics, quantitative finance, math applications, math examples, learning math, ]

Sunday, November 20, 2011

Contextual triviality. What Has to be Done When Someone Uses the Word "Logic".

You can download all the important posts as  PDF book "Unlocking the Secrets of Quantitative Thinking".

When someone uses the word "logic"he/she should immediately point out what is initially assumed to be true/false and what truth results are derived, i.e. what can be proved from those initial assumptions.Word logic is nice to use, it can be fancy, it can show you want to be precise in your communication or explanation. However, the axiomatic system should be known and understandable for all the parties that are part of the "logic" communication. Saying that something is logical doesn't mean it is obvious, and it doesn't mean it does not require a proof. If something appear to be "trivial", the logical context of axioms and premises should be clear to all participants who want to accept that "trivial" remark. Contextually "trivial" is OK.

The other day, while browsing mathematics section at Indigo bookstore, I have noticed a book "Logic for Mathematicians" by A. G. Hamilton, (Google books http://goo.gl/17kEj). I was pleased to see that the book reflects my view that logic is an independent discipline from mathematics and that mathematics is only one of the area of the application of logic. While Frege may have integrated both directions of thinking, I am glad that A. G. Hamilton "presented the subject matter without bias towards particular aspects, applications or developments, but an attempt has been made to place it in the context of mathematics and to emphasise the relevance of logic to the mathematician.".

To me, this is important because of my view (most of the posts in this blog) to differentiate clearly the worlds that define what is to be counted, measured etc, from the mathematical world that accepts pure numbers as starting points. Logic is used in both worlds.



[ logic, mathematical logic, math, math concepts, axioms, mathematics, teaching math, teaching mathematics, understanding mathematics, Frege, Hamilton, ]

Monday, November 7, 2011

Real World Example of Natural Numbers

You can download all the important posts as  PDF book "Unlocking the Secrets of Quantitative Thinking".

In real world application of math we have to keep track what we have counting, while pure math cares only about pure numbers.

This is an example of counting rounds in an UFC match (UFC - I do not approve nor like).



[ math, mathematics, math application, axioms, examples of natural numbers, natural numbers, axioms, sets, number theory, ]

Saturday, November 5, 2011

Free Will

You can download all the important posts as  PDF book "Unlocking the Secrets of Quantitative Thinking".

In the very moment, when you breath, when oxygen molecules split the molecules of your brain biochemical energy storage, the very state of neural firing, dynamics, neurotransmitters rush and retreat that exist at that moment, is the consequence of your free will, the will riding on neural paths configurations and their energy that you release by thinking in exactly that way..at that moment..

Sunday, October 16, 2011

A Few Hints How to Introduce Mathematical Concepts

You can download all the important posts as  PDF book "Unlocking the Secrets of Quantitative Thinking".

Teacher should postpone introduction of strange, exotic mathematical names and labels to, otherwise, most likely, easy to explain and easy to understand concepts in mathematics. Teacher should  first explain mathematical concepts in terms of required sequence of mathematical operations on numbers and on sets involved and then introduce labels or historically accepted names for them. Most of us will agree that many of those names are there for historical reasons, and often they are confusing, misleading, and even intimidating (if Borel, Hausdorff needed so much work to prove that theorem or formulate it, what chances do I have?). To me, it is sometimes better to refer to a theorem by a number first, like Theorem 1, Theorem 2, … and only later assign historical names or other labels to reference them.

Math lectures sometimes look to students like putting misleading, cluttered, over-detailed traffic signs on an easy to use roads and highways.

But, what are we really doing or what we want to do when we say "introducing math concepts through A or B or C real world examples"? Do math concepts need to be introduced through real world examples at all? No, they don't. They can be derived or formulated directly from axioms.  So, what would be the goal of "introducing math" through real world examples? To show that math concepts can be motivated by real life examples, but, at the same time the same math concepts can be derived inside math only, without referencing any real world domain. To me, the mandatory step of introducing some math concepts from real world example is to mandatory show that the same concept can be defined or derived from ZFC axioms. This would clearly show the border and connections, if you wish, at the same time, between applied math and pure math developed from ZFC axioms.

[introducing math, math ], math concepts, math education, mathematics, theorems ]

Saturday, September 3, 2011

What is a number, really?

You can download all the important posts as  PDF book "Unlocking the Secrets of Quantitative Thinking".

In this post I would like to introduce a concept of a number. I want to show a method how we can conceptualize a number, to actually understand what is it. This introduction will provide multiple benefits for anyone interested in deeper, fundamental understanding of mathematics. It can provide answers about what exactly is the subject of research in mathematics. The explanation can be a useful and effective starting point for all those creative minds who ask “why mathematics?” “what for we have to calculate all that?”, and “what is the number actually?”.

Let’s say, to start with, that we can conceptually, visually or in our minds, differentiate objects among themselves, and that we can, and then we want, to count them. When we, for whatever reason, group objects in some collections, we can be in situation to determine which collection has more objects, if we want to. Don’t forget, we don’t have any numbers, or names for counts, defined yet.

How we can determine which set, which collection has more elements, objects?

We can compare collections of objects by matching, pairing, elements from one collection with objects, elements from another collection. Pairing has to be, obviously, one to one.  Let’s say, we have a set of apples and set of pencils, as shown in the Picture 1. We want to find out a number of elements in each set.

We can start first by determining which, if any, set has more elements. In order to do that,  we only need to match, to pair, one object from one set with an object  from another set. If no objects are left unmatched then two sets have the same number of elements. As we can see in the Picture 1, by pairing apples and pencils, no objects are left unmatched, hence these two sets have the same number of elements. We do not have the name yet for that count, for that number, but, the good thing is we know what we are talking about! We are talking about certain number of elements, defined by the exact match of two collections. That property is what we are after, that “numberness” is what we are after.

Now, note one very interesting thing. If we replace apples with pears, and pair, match every pear with every pencil, we can see that the match is again achieved! The pairs are again complete and no pears or pencils are left unmatched. Hence, these two collections, two sets, have the same number of elements. Now, let’s introduce another collection of objects, say watches. Pair the watches with pears. As we can see it’s the same count, complete match, hence the same number of elements. Note very, very interesting observation here! No matter what objects we are matching, as long as the match is one to one, and as long as the pairing is complete, we have the same number of elements in two collections.

It is this property, this “numberness”, common in pairing two sets, that we call a number. You see, no matter what kind of objects are in two sets, if they match, that property, is the actual number. That is the concept of a number! It is, at this point, completely arbitrary how we are going to label this numerical concept we have just discovered and defined. Word, symbol, reference for it is completely arbitrary. In English, it is called number five, and the numeric symbol is 5. Label for our new concept is really of very minor significance at this point. The concept we obtained is way more important than the tag we will use to reference it in our speech. Of course, we could start with three object and obtain number three, or seven objects, and obtain number seven, etc. Notice how we, now, have this set property to work with, set property related to its number of elements, the quantity of objects, that we have abstracted from any two sets of objects, that we can call a number, or a count! That’s the actual concept of a number. Notice, also, how “number” in its essence, is not even a noun, but more like an adjective, that describes “quantitative” aspect of two sets, the number of paired elements of two collections.




Picture 1. One example of number conceptualization.


As long as we know that this labels, 1,2,3,…represents that property of one to one pairing between the elements of two sets (with the goal to determine if they have the same number of elements) we are on a good path to work with numbers and quantification.

You may ask at this point “well, I don’t always see two sets when I count objects of one set, I just count them without any pairing with the elements of another set”. Good question! What you actually do, by, say, counting CDs, in your collection, is matching them with the set of natural numbers in your mind, which is completely ok. But, note, you have natural numbers at your disposal to use them for counting other objects, while in our previous explanation we are actually just defining the numbers! We qwere after very definition of a number. Once the numbers are defined, as we did for number five, you can use that number five and others in counting any kind of objects!

Look at that number five, universal count of five, for any kind of objects. Here is one more interesting conclusion. You see, how at this point, we can deal with counts only! We can deal with a count 3 and a count 5, which we call a number 3 and a number 5, regardless which objects they represent count of! If we want to add them, it will always be 3 + 5 = 8, no matter what we have counted! This is exactly what pure math is about! We, now, can use our generalized knowledge that 3 + 5 = 8, and utilize it any real world situation, for instance, if we have 3 cars and we buy 5 more cars we will have 8 cars.

Note that “purity” of math is just related to the fact that we do not care what we have just counted. We were only interested in adding, subtracting, dividing, pure counts, pure numbers we have abstracted from real world objects counting.

If we want to mix pure math and real world scenarios and objects we are counting, it’s easy! We can just put a small letter beside the number, to keep track what we have counted. Hence, in physics we have 3m + 5m = 8m, for distance, length in meters. Then, also we can put 3 apples + 5 apples = 8 apples in agriculture studies. We essentially do two steps here, during the additions of real objects. When we want to add 3m + 5m, we actually separate pure numbers from the meters counted, we enter with these two numbers the world of pure math, where we do calculation of numbers only, 2 + 3 = 8, and then we go back to real world of meters (because we have those small letters to remind us what we have counted) with the result 8, and associate the name of the object, in this case it’s a physical unit of length, or distance, which is meter, (m), to the number 8. And, voila, we have just used pure math in the real world application!

[ applied math, applied mathematics, concept of a number, concept of a set, natural numbers, number, set and number, set theory ]

Sunday, July 31, 2011

Mathematical Proof for Enthusiasts - What It Is And What It is Not

You can download all the important posts as  PDF book "Unlocking the Secrets of Quantitative Thinking".

With the term mathematical proof we want to indicate a logical proof, i.e. proof using logical inferences, in the field of mathematics. So, it should really be “a proof in the field of mathematics”. Also, we have to assume, and be fully aware, that proof must be “logical” anyway. There are really no illogical proofs. Proof that appears to be obtained (whatever that means) by any other way, other than using rules of logic, is not a proof at all. Assumptions and axioms need no proof. They are starting points and their truth values are assumed right at the start. You have to start from somewhere. If they are wrong assumptions, axioms, the results will show to be wrong. So, you will have to go back and fix your fundamental axioms.
When you have first encountered a need or a task for a mathematical proof, you may have asked yourself "Why do I need to prove that, it's so obvious!?".

We used to think that we need to prove something if it is not clear enough or when there are opposite views on the subject we are debating. Sometimes, things are not so obvious, and again, we need to prove it to some party.

In order to prove something we have to have an agreement which things we consider to be true at the first place, i.e. what are our initial, starting assumptions. That’s where the “debate” most likely will kick in. In most cases, debate is related to an effort to establish some axioms, i.e. initial truths, and only after that some new logical conclusions, or proofs will and can be done.

The major component of a mathematical proof is the domain of mathematical analysis. This domain has to be well established field of mathematics, and mathematics only. The proof is still a demonstration that something is true, but it has to be true within the system of assumptions established in mathematics. The true statement, the proof, has to (logically) follow from already established truths. In other words, when using the phrase "Prove something in math..." it means "Show that it follows from the set of axioms and other theorems (already proved!) in the domain of math..". Which axioms and theorems you will start the proof with is a matter of art, intuition, trial and error, or even true genius. You can not use apples, meters, pears, feelings, emotions, experimental setup, physical measurements, to say that something is true in math, to prove a mathematical theorem, no matter how important or central role those real world objects pr processes had in motivating the development of that part of mathematics. In other words, you can not use real world examples, concepts, things, objects, real world scenarios that, possibly, motivated theorems’ development, in mathematical proofs. Of course, you can use them as some sort of intuitive guidelines which axioms, or theorems, you will use to start the construction of a proof. You can use your intuition, feeling, experience, even emotions, to select starting points of a proof, to chose initial axioms or theorems in the proof steps, which, when combined later, will make a proof. But, you can not say that, intuitively, you know the theorem is true, and use that statement about your intuition, as an argument in a proof. You have to use mathematical axioms, already proved mathematical theorems (and of course logic) to prove the new theorems.

The initial, starting assumptions in mathematics are called fundamental axioms. Then, theorems are proved using these axioms. More theorems are proved by using the axioms and already proven theorems. Usually, it is emphasized that you use logical thinking, logic, to prove theorems. But, that's not sufficient. You have to use logic to prove anything, but what is important in math is that you use logic on mathematical axioms, and not on some assumptions and facts outside mathematics. The focus of your logical steps and logic constructs in mathematical proofs is constrained (but not in any negative way) to mathematical (and not to the other fields’) axioms and theorems.

Feeling that something is "obvious" in mathematics can still be a useful feeling. It can guide you towards new theorems. But, those new theorems still have to be proved using mathematical concepts only, and that has to be done by avoiding the words "obvious" and "intuition"! Stating that something is obvious in a theorem is not a proof.However, using own intuition to construct a proof or to formulate theorem is definitely useful.

Again, proving means to show that the statement is true by demonstrating it follows, by logical rules, from established truths in mathematics, as oppose to established truths and facts in other domains to which mathematics may be applied to.

As another example, we may say, in mathematical analysis, that something is "visually" obvious. Here "visual" is not part of mathematics, and can not be used as a part of the proof, but it can play important role in guiding us what may be true, and how to construct the proof.

Each and every proof in math is a new, uncharted territory. If you like to be artistic, original, to explore unknown, to be creative, then try to construct math proofs.

No one can teach you, i.e. there is no ready to use formula to follow, how to do proofs in mathematics. Math proof is the place where you can show your true, original thoughts.

[ set, set theory, concept of a set, sets in mathematics, real world, applied math, applied mathematics, axioms, math education, math proof, mathematical axioms, mathematical proof, mathematical theorems, mathematics, theorems, tutoring ]

Sunday, July 24, 2011

From Poker, Basketball, Financial Math to Pure Math and Back

You can download all the important posts as  PDF book "Unlocking the Secrets of Quantitative Thinking".

After some initial counting and some thinking put into it, you may have asked yourself, what is there more to investigate about numbers? A number is a number, I have just seen that, a clean and dry concept, a quite straightforward count of objects I have been dealing with. Five apples, five pears, the number five is common to all of them. We have abstracted it, and together with other fellow numbers (three, four, seven, ...) it is a part of a number system we are familiar and we work with. We may have a feeling there are only integers present, and that, really, it is not clear where those mathematicians find so many exotic concepts, so many other numbers, like rational, irrational, and others. Moreover, you may think that, without some real objects to count or measure, there would be no mathematics, and that mathematics is, actually, always linked to a real world examples, that numbers are intrinsically linked to the real world, to the objects counted, measured, that they are inseparable, that a number, despite its "purity", somehow shares properties of the objects it represents the count of.

In this article I will discuss these thoughts, assumptions, maybe even misconceptions. But, no worries, you are on the right track by very action that you put a thought about math and numbers.

Before I go to the exciting world of basketball and poker, as an illustration, let me discuss a few statements. A famous mathematician, Leopold Kronecker, once said that there are positive integers only and that everything else is the work of man. I support that view and essentially many mathematicians do. Here is the flavor of that perspective. Negative numbers are positive numbers with a negative sign. Rational numbers are ratios if two integers. Real numbers (rational and irrational) are limiting values of rational numbers (which are in turn ratios of integers), a sequence of ratios that are smaller and smaller and there are more and more of them, that converge to one value. So, essentially, all these numbers are constructed from positive integers.

As for "purity" of a number here is a comment. Number has only one personality! Take number 5, for instance. It's the same number whether we count apples, pears, meters...That's why we need labels below, or beside, numbers, to remind us what is measured, what is counted, because by looking at the number only we can not conclude where the count comes from. I have written about this in my previous posts. When you write 5 + 3 = 8, you can apply this result to any number of objects with these counts. So, numbers do not hold or hide properties of the objects they are counts of. As a a matter of fact, you can just declare a number you will be working with, say number 5, and start using it with other numbers, adding it, subtracting it etc.. No need to explain if it is a count of anything. Pure math doesn't care about who or what generated numbers, it doesn't care where the numbers are coming from. It works with clear, pure numbers, and numbers only. It is a very important conclusion. You may think, that properties of numbers depends on the objects that have generated them, and there are no other properties of numbers other than describing them as a part of real world objects. But, it is not so. Properties of numbers don't depend on the objects or processes that have generated them. While you can have a rich description of objects and millions of colorful reasons why you have counted five objects, number five, once abstracted, has properties of its own. That's why it is abstracted at the first place, as a common property! When you read any textbook about pure math you will see that apples, pears, coins are not part of theorem proofs.

Now, you may ask, if we have eliminated any trace of objects that a number can represent a count of, what are the properties left to this abstracted number?  What are the numbers' properties? That's the focus of pure math research. Pure means that a concept of a number is not anymore linked to any object whose count it may represent. In pure math we do not discuss logic why we have counted apples, or why we have turned left on the road and then drive 10 km. Pure math is only interested in numbers provided to it. Among those properties of number are divisibility, which number is greater or smaller, what are the different sets of numbers that satisfy different equations or other puzzles, different sets of pairs of numbers and their relationships in terms of their relative differences. That's what pure math is about, and these are the properties a number has.

In applied math, of course, we do care what is counted! Otherwise, we wouldn't be in situation to "apply" our results. Applied math means that we keep track what we have counted or measured. Don't forget though, we still deal with pure numbers when doing calculations, they are just marked with labels, because we keep track by adding small letters beside numbers, which number represent which object. When you say 5 apples plus 3 apples is eight apples, you really do two steps. First step is you abstract number 5 from 5 apples, then, abstract number 3 from 3 apples, then use pure math to add 5 and 3 (5 + 3) and the result 8 you return back to the apples world. You say there are 8 apples. You do this almost unconsciously! You see the two way street here? When developing pure math we are interested in pure number only. Then, while applying math back to real world scenarios, that same number is associated with a specific object now, while we kept in mind that the number has been abstracted from that or many other objects at the first place. This is also the major advantage of mathematics as a discipline, when considering its applications. The advantage of math is that the results obtained by dealing with pure numbers only, can be applied to any kind of objects that has the same count! For instance, 5 + 3 = 8 as a pure math result is valid for any 5 objects and for any 3 objects we have decided to add together, be it apples, cars, pears, rockets.

While, as we have seen, pure math doesn't care where numbers come from, when applying math we do care very much. We care so much what we have counted that we have invented devices to keep track of these counted objects. We have dials that keep track of fuel, temperature, time, distance, speed. Imagine, we have devices which keep track of kind of counted objects so when we look at them and see number five, we will know what that number five represent the count of! Say you have four dials in front of you, and they show all number 5. It is the same number five, with the same properties, and we can say that the power of mathematics is derived from noticing that number 5 is the same for many object and abstracting that number 5 from them, then investigating its properties. Now, here, we went back! We used that universal number five, and keep track in our dials, which exact objects the number 5 represents the count of.

In applied math it is so important to keep what is counted that we have invented dials for those countable objects or measures. There are dials in car, for instance, for fuel consumption, speed, time, engine temperature, ambient temperature, fan speed, engine shaft speed. If it was not up to us, those numbers would float around, like, 5, 2300, 120, 35, 2.78 without knowing what they represent until we assigned them a proper dial units. This example shows the essence of difference between applied and pure math, and how much is up to our thinking and initiative, what are we going to do with the numbers and objects counted or measured.

Now, we may go to great extent to investigate all kinds of properties of all kinds of numbers and sets of numbers. Hence, linear algebra,calculus, real analysis. They are all useful and sometimes very elegant parts of mathematics. But, frequently, we do not need all those properties to apply or use pure math results in everyday situations. Excelling in some business endeavor frequently depends on actually knowing WHAT and WHY something is counted, while, at the same time, mathematics involved, can be quite simple. When I say business, I mean business in usual sense, like finance, trading, but also, I mean, for instance, as we will see soon, basketball, and even poker.

When playing basketball we also need to know some math, at least dealing with positive integers and zero. However, knowledge of basketball rules are way more important than math, in basketball domain.
Those basketball rules are mostly non mathematical, which doesn't make them at all less significant. Moreover, they are way more important ingredient, and more complex part, for that matter, of a basketball game, than adding the numbers. You can have knowledge of adding integers, but without knowing basketball rules, and know how to play basketball, you will not move anywhere in a basketball team or in the game. Moreover, basketball rules are actual axioms of a basketball game. And, every move in the basketball court, any 30 seconds strategy developed by one team or the other, corresponds to theorems of the basketball game! Any uninterrupted part of the game, without fouls or penalties, is an actual theorem proof, with basketball rules as axioms. We can say that basketball rules are those statements that define what belongs to a set "number of scored points"! You see here how we have whole book of basketball game rules that serve the purpose to define what belongs to a set (of scored points). Compare that to those boring, and sometimes, ridiculous examples, in many math texts, with apples, pears, watermelons (although they may illustrate the point at hand well). With ridiculing the importance of rules of what belongs to a set, belittling their significance and logic associated to obtain them, those authors, unintentionally, pull you away from an essential point of "applied" math - in order to define what belongs to a set, and then, count it (like points in basketball) you need to know areas other than math, and to develop, logic, creativity, even intuition in those areas, in order to decide what really belongs to a set and what needs to be counted. Because, accuracy of rules and logic to determine what belongs to a set dictates the set's cardinality, the size of the set, the number of its elements. And this is the number you will enter in all your calculations later! Note, also, that only knowing rules of basketball game doesn't make you a first class player, nor your team can be a winner just knowing the rules. You have to develop strategies using those rules. You have to play within those rules a winning game. The same is in math. Knowing the fundamental axioms of math will not make you a great mathematician per se. You have to play "winning game" inside math too, you have to show creativity in math as well, as you would in basketball game!

In business it is often more important to know where the numbers are coming from than to know in detail their properties. For instance, in poker. again, only integers are involved. You have to remember that the same number 5 can be any of the card suits, and, in addition, can belong to one or more players. Note how abstracting number 5 here and trying to develop pure math doesn't help us at all in the game. We have to go back, we have to use that abstracted number 5 and put it back to the objects it may have been abstracted from. You have to somehow distinguish that pure number 5, and associate it with different suit, different player. And strategy you develop, you do with many numbers 5, so to speak, but belonging to different sets, suits, players, game scenarios. Hence, being a successful poker player, among other things, you need to memorize, not exotic properties of integers and functions, but how the same number 5 (or other number) can belong to so many different places (players, suits, strategies, scenarios).

Another example is finance. Any contract you have signed, say for a credit card, is actual detailed definition what belongs to a set, i.e. whether $23,789.32 belongs to your account under the conditions outlined in the contract. Note how even your signature is a part of the definition what belongs to a set, i.e. are those    $23,789.32 really belong to your account. You see, math here is quite simple, it is a rational number   23.789,32, but what sets it belongs to is outside mathematics, it's a domain of financial definitions. Are you going to pay the bill of $23,789.32, or someone else, is a non mathematical question, while mathematics involved is quite simple, it's number 23,789.32.

Now, note, when you are paid for your basketball game, suddenly you have math from two domains put together! It may be that the number of points you scored are directly linked to a number of dollars you may be paid. Two domains, of sport and finance, are linked together via monetary compensation rules, which can have quite a bit of legal background too, and all these (non mathematical in nature!) rules dictate what number, of dollars, may be picked after the set of games.

A theorem in one system is usually an axiom in another. Which systems to link in this way is in the center of innovative thinking.

[ applied math, applied mathematics, math applications, poker, basketball, financial math, poker and math, math concepts, financial mathematics  ]

Friday, July 22, 2011

Concept of a Set and of a Number

You can download all the important posts as  PDF book "Unlocking the Secrets of Quantitative Thinking".

For instance, let's take a look at the cars on a highway, apples on a table, coffee cups in a coffee shop, pears in a basket. Without our initiative, our thought action, will, our specific direction of thinking, objects will sit on table or in their space undisturbed and unanalyzed. They are apples, cars, coffee cups, pears. But then, on the other hand, we can think of them in any way we wish. We can think how we feel about them, are they edible, we can think about theory of color, their social value, utility value, psychological impressions they make. We can think of them in any way we want or find interesting or useful, or we can think of them for amusement too. They are objects in the way they are and they need not to be members of any set, i.e. we don’t need to count them.

Now, imagine that our discourse of thought is to start thinking of them in terms of groups or collections, what whatever reason. Remember, it's just came to our mind that we can think of objects in that way. The fact that the apples are on the table and it looks like they are in a group is just a coincidence. We want to form a collection of objects in our mind. Hence, apples on a table are not in a group, in a set yet. They are just spatially close to each other. Objects are still objects, with infinite number of conceptual contexts we can put them in.
Again, one of the ways to think about them is to put them in a group, for whatever reason we find! We do not need to collect into group only similar objects, like, only apples or only cars. Set membership is not always dictated by common properties of objects. Set membership is defined in the way we want to define it! For example, we can form set of all objects that has no common property! We can form a group of any kind of objects, if our criterion says so. We can even be just amused to group objects together in our mind. Hence, the set can be specified as “all objects we are amused to put together”. Like, one group of a few apples, a car, and several coffee cups. Or, a collection of apples only. Or, another collection of cars and coffee cups only. All in our mind, because, from many directions of thinking we have chosen the one in which we put objects together into a collection.

Without our initiative, our thought action, objects will float around by themselves, classified or not, and without being member of any set! Objects are only objects. It is us who grouped them into sets, in our minds. In reality, they are still objects, sitting on the table, driven around on highways, doing other function that are intrinsic to them or they are designed for, or they are analyzed in any other way or within another scientific field.

Since, as we have seen, we invented, discovered a direction of thinking which did not exist just a minute ago, to think of objects in a group, we may want to proceed further with our analysis.
Roughly speaking, with the group, collection of objects we have introduced a concept of a set. Note how arbitrary we even gave name to our new thought that resulted in grouping objects into collections. We had to label it somehow. Let's use the word set!

Now, if we give a bit more thought into set, we can see that set can have properties even independent of objects that make it. Of course, for us, in real world scenarios, and set applications, it is of high importance whether we counted apples or cars. We have to keep tracks what we have counted. However, there are properties of sets that can be used for any kind of counted objects. Number of elements in a set is such one property. If we play more with counts and number of elements in a set we can discover quite interesting things. Three objects plus six objects is always nine objects, no matter what we have counted!  The result 3 + 6 = 9 we can use in any set of objects imaginable, and it will always be true. Now, we can see that we can deal with numbers only, discover rules about them, in this case related to addition that can be used for any objects we may count.

Every real world example for mathematics can generate mathematical concepts, mainly sets, numbers, sets of numbers, pair of numbers. Once obtained, all these pure math concepts can be, and are, analyzed independently from real world and situations. They can be analyzed in their own world, without referencing any real world object or scenario they have been motivated with or that might have generate them, or any real world example they are abstracted from. How, then, conception of the math problems come into realization, if the real world scenarios are eliminated, filtered out? Roughly speaking, you will use word “IF” to construct starting points. Note that this word “IF” replaces real world scenarios by stipulating what count or math concept is “given” as the starting point.
But, it is to expect. Since a number 5 is an abstracted count that represents a number of any objects as long as there are 5 of them, we can not, by looking at number 5, tell which objects they represent. And we do not need to that since we investigate properties of sets and numbers between themselves, like their divisibility, which number is bigger, etc. All these pure number properties are valid for any objects we count and obtain that number! Quite amazing!

Moreover, even while you read a book in pure math like "Topology Fundamentals" or "Real Variable Analysis" or "Linear Algebra" you can be sure that every set, every number, every set of numbers mentioned in their axioms and theorems can represent abstracted quantity, common count, and abstracted number of millions different objects that can be counted, measured, quantified, and that have the same count denoted by the number you are dealing with. Hence you can learn math in the way of thinking only of pure numbers or sets, as a separate concepts from real world objects, knowing they are abstraction of so many different real world, countable objects or quantifiable processes (with the same, common count), or, you can use, reference, some real world examples as helper framework, so to speak, to illustrate some of pure mathematical relationships, numbers, and sets, while you will still be dealing, really, with pure numbers and sets.

There may be, also, a question, why it is important to discover properties of complements, unions, intersections, of sets, at all? These concepts look so simple, so obvious, how such a simple concepts can be applied to so many complex fields?

Let’s find out! Looking at sets, there is really only a few things you can do with them. You can create their unions, intersections, complements, and then find out their cardinalities, i.e. sizes of sets, how many elements are there in a set. There is nothing else there. Note how, in math, it is sufficient to declare sets that are different from each other, separate from each other. You don’t have to elaborate what are the sets of, in mathematics. You do not even need to use labels for sets, A, B, C,… It’s sufficient to imagine two (or more) different sets. In mathematics, there are no apples, meters, pears, cars, seconds, kilograms, etc. So, if we remove all the properties of these objects, what properties are left to work with sets then? Now, note one essential thing here! By working with sets only, by creating unions, complements, intersections of sets, you obtain their different cardinalities. And, in most cases, we are after these cardinalities in set theory, as one of the major properties of sets, and hence in mathematics. Roughly speaking, cardinality is the size of a set, but also, after some definition polishing, it represents a definition of a number too. Hence, if we get a good hold on union, complement, intersection constructions and identity when working with sets, we have a good hold on their cardinalities and hence counts and numbers. And, again, that's what we are after, in general, in mathematics!

As for real world examples, you may ask, how distant is set theory or pure mathematical, number theory from real world applications? Not distant at all. Remember the fact how we obtained a number? A number is an abstraction of all counted objects with the same count, of all sets of objects with the same number of elements (apples, cars, rockets, tables, coffee cups, etc). Hence, the result we have obtained by dealing with each pure, abstracted number can be immediately applied to real world by deciding what that count represents or what objects we will count that many times. Or, the other way is, even if we dealt with pure math, pure numbers all the time, we would've kept track what is counted, with which objects we have started with. There is only one number 5 in mathematics, but in real world applications we can assign number 5 to as many objects as we want. Hence, 5 apples, 5 cars, 5 rockets, 5 thoughts, 5 pencils, 5 engines. In real world math applications scenarios it matter what you have counted. But that fact and information, what you have counted (cars, rockets, engines, ..) is not part of math, as we have just seen. Math needs to know only about a specific number obtained. Number 5 obtain as a number of cars is the same as number 5 obtained from counting apples, from the mathematical point of view. But, it can and does represent sizes of two sets, cars and apples. For math, it is sufficient to write 5, 5 to tell there are two counts, but for us, it is practical to drag a description from the real world, cars, apples, to keep track what number 5 represents.

[ concept of a set, math, math tutoring, mathematics, number concept, number definition, numbers, set, set concept, sets and numbers, tutoring ]

Monday, July 18, 2011

Twitter - Insights About Creative Thinking, Science, Mathematics, Logic, Intution, Innovation.

You can download all the important posts as  PDF book "Unlocking the Secrets of Quantitative Thinking".

Science is way more than math and logic. Math and logic can be equally applied do dogmatic teachings as well. Specific assumptions are the ones that define science.

Scientific thinking is much more than math. Quantification is often necessary but in no way sufficient condition for a scientific discover.

Human values are the ones that can relate, connect different axiomatic systems, and make them work together. It is the framework of human values that dictates which selection of theorems from different axiomatic systems we will make.

Math and logic do not imply right away that scientific thinking takes place. Math and logic will equally well serve any non scientific thinking, like a dogmatic teaching. It is the assumptions that differentiate scientific from non-scientific direction of thinking. Scientific assumptions are the ones that wins. Math and logic just serve them well.

Mathematics is defined not by objects it counts, nor by reasons or logic why those objects are counted, but with concepts used to define mathematics axioms and to define proofs of mathematical theorems.

In real world mathematics application, it is you who guides quantification. Guided quantification is the core of free applied math thinking. 

Numbers have properties of their own, independent of anything else. Hence, real world  can only specify starting points for calculations, and perhaps the sequence of numerical operations, but it can not influence, or change, in any way, these intrinsic properties of numbers within the mathematical system. And, on the other hand, a mathematical system, or numbers' properties, can not tell to which particular real world example they may be applied or be relevant to.

Allow complete creative freedom to play with initial assumptions then use strict logic to find true consequences.

It is the interplay of imaginative assumptions that lead to discovery. Only after the nested assumptions interplay logic should kick in.

Feel free to assume, propose anything you can imagine and only after that use logic and maybe math, to explore validity of your assumptions.

Logic and (possibly) some quantification should only be good servants to your uninhibited, creative, free thinking and assumptions play.

Logic can tell you if your assumption, premise is wrong. But logic, then, cannot tell you what would be the correct assumption or premise.

You use logic to TEST your assumptions. Logic hardly can help you to discover the correct assumption at the first place.

Behind all math initial premises and starting numbers may be a real world story explaining why the premises are there.

You can assume anything then apply correct logic. Only consequences will prove if your assumptions were true/correct.

Intuition, common sense, and experience probably served as the first quantitative tools for price setting. - "Energy Risk" by D. Pilipovic.

A mathematical model of a process is a set of premises driven by world extraneous to math yet they can be derived directly from math axioms

Force, energy, speed, momentum, inertia are not part of math. If they were, then math theorems will be proved using them. It's not the case.

What you may have to tell your primary school students when explaining math and a concept of a number - http://t.co/PkI7VdQ

Math can't tell real world from fictional one! Look! If Harry Potter flies 10 m/s how many meters he will advance after flying 5 seconds?

The very moment you said "as many apples as oranges" you defined the concept of a pure number. Moreover, no need to name the number.

More magic than in a new Harry Potter movie - take a journey from real world math applications to pure math and back http://t.co/PkI7VdQ

Take a thought journey from real world math applications to pure math and back - and have that "wow!" moment http://t.co/PkI7VdQ

Labeling a number generation as "random" is not part of mathematics. It's an attempt to describe some number selection by ordinary language.

Everyone, especially primary and secondary school math teachers, may consider reading Paul Lockhart's "A Mathematician's Lament".

To develop all mathematics you do not need a single other science. No need for physics, quantum physics, genetics, quantum chemistry,...

Whole math can be developed inside heads of mathematicians, without any pencil, paper, given they have enough big memory.

Math for [insert the field of application here] . It only means that you decide WHAT is counted and why. Math axioms and theorems remain the same!!

How math can be applied to so many different fields and how we can use math in real life http://t.co/17QRRxV

Math is not about following directions, it's about making new directions. - Paul Lockhart, "A Mathematician's Lament"..

If you asked yourself Can I revisit my math from primary and secondary school and finally understand what is it about? http://t.co/17QRRxV

In order to even begin to count something, you have to know legal system, exchange rules, physics laws, economic laws, how to measure, ..

While membership to a set is not defined within math, it has exotic names outside it: transaction, ownership, buy, sell, exchange, measure..

The very method we quantify something (like measurement) is not a part of mathematics! Set and membership to a set are undefined within math.

Why would you use real world example for a math concept when you can derive it directly from axioms? Both approaches should be demonstrated.

Logical truth values entered the irrational world of emotionality with the statement 'true love'.

Logical truth values entered the emotional world of irrationality with the statement 'true love'.

To me, two core concepts to know for aircraft design are combustion reaction energies (bond energies, fuel, oxygen) and airfoil physics.

More than 20 motivational examples to introduce rational numbers to kids. Pirates, scuba diving, text messaging, pets ..http://t.co/j7N6QAc

You don't deny student's hate towards math, nor try to change it directly. Instead, you accept it and integrate their hate in math puzzles.

Field of math application shapes the math development in the same way the landscape shapes and guides the roads going through them.

While pure math is like building roads just to build them, applied math is like building roads through landscapes you want to go through.

Math lectures sometimes look to students like putting misleading, cluttered, over-detailed traffic signs on easy to use roads and highways.

It is way better to first explain math concepts in terms of required operations and sets of numbers they apply to, and only after that.....to label them with historical, outdated, misleading, confusing names that contribute nothing to the concept's definition.

It is way better to first explain math concepts in terms of required operations and sets of numbers they apply to, and only after that...

To calculate racing track length you need limit concept. For racing car fuel usage you need rational numbers. Teach both at the same time.

Knowing how to implement a business rule in C++ can make you a living. Knowing what business rule you will implement can make you a fortune.

Math and physics concepts should be think of only by the ways they are calculated. Ordinary language names are confusing, often misleading.

We talk about selling, buying, getting, sending energy, but energy is not an object. It's a calculated value from measuring mass, time, distance.

Internal combustion engine principle for beginners. Combustion is, in essence, an electrical reaction. - http://t.co/qxk6PF5

Different contexts will give different meanings for the same sentence. #semiotics

From real world math applications to pure math and back! http://t.co/PkI7VdQ

For many students, math looks like a maze. Students are lost in one area of maze while real fun with math is in the other part of maze.

High school math programs are like labyrinth for students. Students should get a hot balloon and take a bird view look where they are.

Student hates math? Integrate his resistance points, reasoning, into the math problems. Student will realize that he dictates quantification.

Student hates math? Milton Erickson wrote about utilizing person's resistance to a subject to, actually, achieve goal person is resisting to.

Motivation & Math for students who hate math. Ask what is the percentage of time they would do math compared to what they like to do daily.

Here is one motivational math example. Ask your students in how many ways they HATE math.

Awareness - making visible new axiomatic system not known to exist before. Truths presented in order to take action i.e. derive theorems.

Aeronautical Engineering, Aerodynamics, Aircraft Design References http://t.co/nce2gAQ #aviation #aircraftdesign

Math and magazine design. Designer has to know how to fit actor's surface area to the page dimensions. Lower and upper bound...

Emotions and math? He wrote very emotional Acknowledgment in his new book on Advanced Calculus.

Applied math can not be solely credited to the achievements in the applied field. Field dictates what, when, why is to be calculated.

Grammar can not be credited for a beauty of a literary work. Many stupid things are said using perfect grammar, and vice versa.

Saying that math is backbone of things is like saying that grammar is backbone of every single novel, science paper, literary work created.

From ZFC axioms you can create all math. Yet, it is the world extraneous to math (often non-axiomatized) that dictates math development.

Axiomatizing one system strangely isolate reasoning world outside of that system, thus hiding the motivation logic for system's theorems.

Once you hear word "axioms" (in any system), look for logic extraneous to that system. That's where motivation for theorems is coming from.

Motivational Math. Introducing Math Through Car Racing Concepts. Stay tuned for a new, exciting article! http://t.co/4ibp7w8

Even if you manage to, somehow, quantify right and wrong, you still need their firm definitions to be sure you are not quantifying..apples.

Whenever, in a physics textbook, you see phrase "arbitrary" (magnetic, electric field...), it's a placeholder for a design driven value.

Many math proofs start with "Let's assume...". But, wait! Can you explain where that starting assumption comes from?? #mathed

Assumptions coming from non-axiomatized fields (physics, economics, finance) can wreak havoc when used in a strict axiomatic system (math).

If mathematicians are so proud of their axiomatic approach, why they deal at all with applied math in non axiomatized fields??

How we are allowed at all to go from non axiomatic world, physics, economics,finance, to so strictly defined axiomatic world of mathematics?

You don't learn math, then apply it. Newton didn't learn calculus first (there was none, he invented it!), then applied it to physics.

While a proof, in math, has to be very logical and precise, the genesis of it is usually described as art or unexplainable inspiration.

Strict, precise Newton's Law of Gravitation does not prevent you to enter into it a completely random number for mass or distance.

Length of a musical note as a mathematical property has way less significance than emotional perception of the sound (note) of that length.

Surface and volume integrals should be explained using tattoos. They are a good example for arbitrary surface and ink volume calculation.

Things You Always Wanted to Know About Math * But Were Afraid to Ask http://t.co/PkI7VdQ

From Real World Math Applications to Pure Math and Back http://t.co/PkI7VdQ

You spent all your school years dealing with continuous functions only to hear after they are very small number of all functions of interest.

When I hear "it's just continuous function"..bad! No, it's not "just"! It took hundreds years to come up with the definition of continuity.

I would ban phrases "it's simply...(that)", "it's just...(that)" in math. Please leave to student to judge is it complicated or simple.

It's useful to quantify, but, relationships that are quantified are OFTEN quite non-mathematical.

A math proof, once you do it, is probably the only thing in math you are not obliged to explain your teacher how you did it.

Logic used in math proofs is the same as logic used in law. But, in law, axioms are fluid, relative, changing. Law is doing best it can!

Using logic or not, people are making decisions each and every day..

Can you master math? I think, yes! http://t.co/1J31IRE

Explaining essential ideas of mathematics. Talk about Applied Mathematics, Mathematics and Real World, Math Education. http://t.co/aVTTz4v

Puzzled with math graphs? Wondered why they use them? Where the graphs come from anyway?? http://t.co/lGLUfHq

Math and Film. "They had tied up all mathematics of plots and substructures and sub-characters." -Johnny Depp, interview, Cineplex Magazine.

Overheard in student cafe: Math text often starts with 'Lets suppose..'. I don't want to suppose anything, especially something THAT complex.

You can quantify and calculate as much as you want, but if you don't think scientifically, mathematics can't help you.

There are many scientific discoveries that has nothing to do with quantification nor math.

Math may be necessary, but definitely it's not sufficient part to make progress in science.

Every proof should be constructed within known and accepted axiomatic system, being it physics, math, economics, law, engineering.

An explosion into unknown..http://explainingmath.blogspot.com

The posts are terrific. They engulf! http://explainingmath.blogspot.com

Usage of a math theorem is in NOT dependent AT ALL on the way theorem is proved. How you use a theorem has nothing to do with its proof.

To understand a math proof is way easier than to make a proof, in the same way it's easier to consume a movie than to make it, or to appreciate an art painting than to make it.

There is no straightforward path how to prove math theorems, as there is no law that can predict what number you will chose right...NOW.

Updated article why graphs are chosen to visually represent quantities in math, physics, economics etc...http://t.co/lGLUfHq

At some point teachers should stop explaining math concepts with real world examples because none of theorems are proved by using apples.

Mathematics can not be Queen of all sciences because you can't start only with math and develop other sciences. Science is there first.

Math without science, i.e. without science to tell WHAT is counted and WHY is just play with numbers (but elegant, logical, often exciting).

At some point teachers should stop explaining math concepts with real world examples becuase none of theorems are proved by using apples.

Even word "RANDOM" does not belong to math. It's outside math as is measurement, observation, guess etc. Math sees only numbers given to it.

How to Teach Your Kids and Yourself to Think More Freely About Math and Real World Math Applications ... http://t.co/1J31IRE

Teachers should clearly explain the difference between lingustic framework within which math tasks are described and pure math itself. #math

Since differential equation specifies only the difference between two quantities, it can not tell you with which quantities to start with.

Math can't tell you what to count. Math deals only with numbers and a result of any math task is a number, and a number only.

Hockey, Physics, Axioms and Where Innovations Come From..http://t.co/ZGwvm6y #hockey #physics #innovation

Imagine creating rules of the game what to do with numbers. Then, new theorems will be dictated by this game. Without game - no theorems.

In math it is YOU who creates territory and then investigate its properties and boundaries.

If you want popular introduction to rational, irrational numbers you may want to read "Essays on the Theory of Numbers" by Richard Dedekind.

How to approach numerical values in a physics formula. How to much better understand and use physics formuls...http://t.co/i2vNn6J #physics

I would strongly recommend "Essays on the Theory of Numbers" by Richard Dedekind. Detailed and non boring introduction to continuity.

Math is not prerequisite for real world applications. Newton did not learn calculus then applied it. He invented calculus!

What would you like to do, what you have a talent for, and what economy, i.e.market is looking for can hardly be all found in one job.

During schooling (don't mix that with education!) best thing you can do is to follow your own ideas and ask, then answer your own questions.

Motivation to Use Graphs in Math, Physics and to Know Arbitrary Surface Area Calculations, http://goo.gl/gPXFE

Quantitative finance, dragons, and math - http://goo.gl/XEDL3

Relationships between dragons lead to math development... http://goo.gl/XEDL3

Math can be motivated by real world or by fictional world. It can also be developed independently from both worlds. Student should know that.

Math can't distinguish between REAL world and FAIRY TALE! Check this. Two dragons ate 53kg of coal each. How much coal they ate together?

You can assign EXACT number to any RANDOM event! :-)

In many cases, relationships (between objects) that define WHAT has to be calculated are far more interesting than calculations themselves.

Value of calculus: when you find something interesting to calculate, it can help! The trick is to find something enjoyable to analyze.

You can understand calculus too! How to Calculate Surface Area of an Arbitrary Shape - Story of Pirate Island http://goo.gl/hbVEY

Math deals ONLY WITH NUMBERS, COUNTS. However, math can be used in real life once you start keeping track WHAT is counted and why.

It is seldom that an airfoil camber line can be expressed in simple geometric or algebraic forms. Important illustration of a math function!

Sure, mathematics can make you think better, especially if YOU set and define ORIGINAL problems, and not only solving what you are told to.

Airplanes, pirates, treasure hunt - how to introduce calculus ideas to primary school students. http://goo.gl/9uaPr

More about Setology and Countology here http://goo.gl/rAPWx #math #mathematics

Mathematics = Setology. A science about sets. :-)

Mathematics = Countology. It's a science about counts. Sort of better than Numerology :-) Count is a required action that gives a number!

How math can be applied to so many different fields and how we can use math in real life http://goo.gl/cJQxs

Students are afraid to PICK a number by themselves. They think each number has to be calculated, obtained in some complicated manner.

Stochastic process PICKS a number. Physical measurement PICKS a number. Picking a (closer and closer) number is ESSENCE of limit definition.

Physical or any process doesn't "generate" numbers. It PICKS numbers. Numbers are already generated, defined inside mathematics.

Graph is an invention of using length as a representation of ANY imaginable measurable quantity or number.

Introducing math function to students: first step should be to let students draw an arbitrary curve and show it represents PAIRED numbers.

"Our education plays a trick with us, leading us to believe things which are not correct." BBC Environment, Geometry, http://goo.gl/BaFKQ

Many are looking for real world examples of math. But, math can't tell what is real and what's not! 5 dragons plus 3 dragons = 8 dragons!

You apply math only AFTER you chose WHAT to count. Hence, choosing WHAT to count and WHY it is counted has nothing to do with math!

Have you ever wanted to know what are the fundamental ideas in calculus? http://goo.gl/aVDbv

But, you don't have to even say "Trust me, I am a lair.". You can just say "I am a lair.". It's already a paradox.

Journey to the Pirate's Island to learn calculus ideas...like a treasure hunt, sort of..http://goo.gl/hbVEY

Have you ever thought what's behind calculus ideas? Maybe this will show just that! http://goo.gl/hbVEY #math #calculus

How to introduce calculus concepts to primary school students: "How to Calculate Surface Area of a Pirate Island" http://goo.gl/hbVEY

After they master basic algebraic operations, primary school students should be encouraged to define new math problems by themselves. #math

Here is my illustration of the Pirates Island at night, which will be used to introduce integration to students, http://goo.gl/BipFE

My new draft post "How to Calculate Surface Area of a Pirate Island" introducing integration to primary school students http://goo.gl/rVY1D

Many students see math, if not whole formal education, as a tunnel from which they have to get out, eventually, to do what they want.

How the rational numbers should be introduced to kids, http://goo.gl/dhUmS #math #rationalnumbers

Once we realize that math deals only with sets and numbers and that math does not need real world for examples, we can accept desire ...mathematicians to explore properties of numbers and their relations, without even thinking is there any "real" world application.

Real world can give math some initial counts, numbers, even sequences of required operations. But that's it. Math takes off by itself after.

While a proof, in math, has to be very logical and precise, the genesis of it is usually described as art or unexplainable inspiration.

Math can't tell you why you added two numbers but once you added them math can tell you what properties they have compared to other numbers.

Limiting process, in mathematics, may not itself lead to exact value, but, it can serve to point to where that value is, or can be.

Irrational numbers cannot be represented as a ratio of two integers? But, they are still infinite sum of ratios of two integers. So......?

Students should be shown that all the other numbers, rational, real, imaginary, transcendent, irrational, are CONSTRUCTED from integers.

Sunday, July 3, 2011

Mathematics Through Car Racing Concepts. Physics, Car Design, and Driver's Inputs...


You can download all the important posts as  PDF book "Unlocking the Secrets of Quantitative Thinking".

Car racing is a captivating sport for many of us. It is very interesting sport for kids as well and that fact can be used to motivate some important concepts in mathematics. Car racing track, with its irregular shape, dictated by urban projects requirements and geography, can be used to introduce calculus, integration, rational, irrational numbers, finding the length of the curve of arbitrary shape, finding the surface area enclosed by racing track, which is also of an arbitrary shape. Kids would be more interested in math if they can be shown the applications in things they are interested in.

Examples you can use. Speed of Formula 1 cars (256.78 km/hr), time of arrival, fuel consumption (72.59 L/km), engine temperature (985.23 C), laps counts (2.5), tire rubber temperature, pit time (58.5 sec), randomness of pit times (probability distribution, average, expectation), track length (10.25km), compare tire diameter, volume with the length of the track.

When talking about racing car related concepts, care should be taken to explain the existance of logic and functional relationship between objects that will be, possibly, quantified later. This approach is important when using any real world example for mathematics. For instance, it should be signified that business, social, geographical, financial analysis was done before a race track is built. Hence, business, social, geographical, financial analysis dictated a number that you will obtain later by measuring the length of the track. In this framework, student should be shown that there are non mathematical relationships that dictates the shape, size, volume of objects that can be quantified later.

Looking at a number of cars that participate in a race, a function, as a mathematical concept, can be introduced. Moreover, functions of several variables can be introduced considering that each car travels different path, with different speed, uses different amount of fuel, engines have different temperatures, drivers change gears different number of times per minute, pit stops are of different length, and drivers complete the race at different times. Winning a race can be shown to depend on several mathematical parameters too, plus the skill of the driver. Randomness that is present in some of these measurable parameters can be used to introduce probability concept, stochastic processes, statistics.

But, when the driver of a racing car drives the car, he is generating quantifiable entities. He is dealing with objects and events that has mutual quantitative relations in addition to other relationships, like mechanical for instance, or spatial, or temporal. He is generating numbers, giving initial and boundary conditions for a number of PDEs and IDEs in mechanics, thermodynamics. He may be not aware that he is generating numbers. He does not think too much mathematically while driving a car, nor thinks about physics laws that take place every moment. The drivers is involved in the specification of physical initial and boundary conditions for those physics laws. Pressing the gas, accelerator pedal, steering the wheel, using the breaks. The driver knows what the output will be for his inputs. There is of course, a feedback from the car measurements system, providing him with certain important numbers, like fuel gauge, speed dial, temperature, tyre pressure. Given the context of race, and driving the car, these numbers will influence his decision about physical inputs to the car system, like slowing down perhaps, or accelerating.

An engineer, car designer, engine designer, must predict the range, the envelope of values that the car will be subjected to. These values will be dictated by the driver later. However, the engineer who designed the engine and knows the racing car mechanics and functioning inside out may not be a good racing driver, and usually is not allowed to race. His intrinsic knowledge of car design, mechanics, and thermodynamics usually doesn’t help when it comes to fast thinking when to turn left or right on the racing track, when to accelerate or slow down, meaning engineers role is to design a car for specified range of possible characteristics. It is not the physics laws that win the race. It is the selection and sequence of initial and boundary conditions provided to the physics laws, or more preciously, to the car components that behave in accordance to physics laws. Physics laws are the same for all racing car drivers in the race. It is this selection of initial and boundary conditions that decide who will win the race. Note, also, how here physics and mathematics touches on social values. We value who comes first in the race, not the discovery of physics laws and the mathematics used during the design process. Good car design, brilliant engineers, physicist, and mathematicians can make an excellent car. They know very well the math and physics and engineering. But, there is no physic or mathematical law that will specify the initial and boundary conditions that will win the race. It is up to driver to input them into the car while racing, given the information he is getting on the track, during the race, about his own position, positions of other drivers, their speed, track characteristics, etc.. Moreover, same type of car, with same characteristics, driven at the same time by different drivers, in an race, will show the significance of the initial and boundary conditions selection to the PDEs and IDEs underpinning the engine performance and car functioning in general.

Every set of action while driving a racing car is to the race like an invention is to the laws of physics. Maxwell’s equations are great discovery, but they are necessary, yet not sufficient condition to make an invention or a novel engineering solution. It is the set of initial, boundary conditions, and specific configuration of elements that are part of the winning invention. And there are no laws, nor formulas, in mathematics or physics, that will let you produce inventions one after another.

Note also, how financial mathematics is linked, via logical connectives” IF…THEN” to the car racing. The winner is awarded say $500,000. So, IF your driver wins, THEN he will get $500,000. See how the context defines what will be said about truth values of events at the car racing. It is us, or rather, the Sports Governing body that specifies what will happen after that “THEN…”. That’s the axioms of the Car racing Award. It is not known what can be put there after “IF your driver wins THEN….”. It can be that he will get ice cream or, his car will be painted in red. Who knows? It is us who specify these logical statements and build a system from it.

It should be shown to students that numbers generated in a car race can come from different sources, and can be generated in different ways. They can be a product of driver's decisions, physics laws, random events, and should be shown that mathematics accepts all those numbers in the same way, as numbers only. It is us who keep track where the numbers come from, when, and why, as I have written about that in my previous posts.


[ applied math, applied mathematics, car racing, cars, cars movie, film cars, Honda, Honda Indy, math concepts, motivation, movie cars, racing sports cars ]

Monday, June 27, 2011

From Real World Math Applications to Pure Math and Back

You can download all the important posts as  PDF book "Unlocking the Secrets of Quantitative Thinking".

Can you go from pure math to real world math applications? The answer is no. You can not start with math only and then “apply” to real world scenario. It is, however, possible to use math in real world (even in fictional world, like in Harry Potter movies), practical applications, but the path and direction are different and needs to be clarified.

The reason you can not go from pure math to real world math application is in the fact and in the nature, definition (in a sense) of a number. A number is obtained as an abstraction, a common property for many objects. By this very definition, because it is abstracted from counted objects, because it is, now, a separate concept, representing a pure count, without any object associated to it, you can not tell, by looking at the number only, where it came from, what and if anything has been counted to obtain that number. In other words, a number does not carry any information about any object extraneous to mathematics! Hence, you can not say, just looking at the number only, or at the sequence of math operations on numbers, what its or their application, in real world, may be. Newton did not learn calculus first, then applied it to the gravitational problems! Quite the opposite happened. Newton was dealing with non mathematical objects and relationships like apple falling from the tree, Moon orbiting Earth, and other body motions. Unless they are quantified, these are not mathematical objects nor relationships. If they were, then you would see theorems in math books proved by apples, Moon, speed, etc. but it is not so. Math theorems are stipulated and proved using only mathematical objects, like numbers, sets, set of numbers, or other mathematical theorems and axioms. So, let make that clear, Newton first dealt with physical objects and only then he invented calculus. So, when someone tells you you will learn math then apply it, it is not quite true.

When you deal with a number, you deal with an abstracted common property, a separated concept abstracted from all the objects whose count it represents. The very moment you start adding 2 apples and 3 apples you are doing two distinct steps. First one is recognizing that the object to be counted is an apple. That recognition process, a categorization, that you are looking or holding an apple is outside mathematics, since you can be counting apples, pears, cars, books, cups. This recognition is a focus of research of cognitive science, psychology, biology, color research, even socal sciences. The second step (which is, actually, common to counting all those objects) is dealing with numbers 2 and 3. Even if you may not notice, when dealing with 2 and 3, you are dealing with counts that can represent not only apples, but millions of other objects that can be counted, or put in sets, then counted, to obtain 2 and 3. Hence, the result you obtained for 2 and 3 apples, i.e. 2 + 3 = 5, can be used in ANY other situation where you have 2 objects and 3 objects and you want to add their counts. You right away invented and used "pure" mathematics when counted these apples. It is this universality, the common numeric property of counted objects, that gives mathematics ability to be a separate discipline, to deal only with numbers. While to us, and to the field that uses quantification, is very important what, when, why and where something is counted or measured, to investigate only the counts' properties is the task of pure math. Pure math does not care where the numbers or counts are coming from. It is very similar when we create a set of any objects (of interest), but we are only interested how many elements are in the set and not which objects are part of the set (that information, which objects are elements of the set, we keep track of on a separate sheet of paper) ! Math knows and should know only about numbers and sets of numbers. Notice how math may be "motivated" by counting apples, but, the result obtained, i.e. 2 + 3 = 5, can be used when counting any other objects!

Also, math can't tell real world from fictional one! Look! If Harry Potter flies 10 m/s how many meters he will advance after flying 5 seconds?

Mathematics deals with numbers and with numbers only. It does not care where the numbers are coming from (but, in the field of applied math, we do care where the numbers are coming from). Now, you may ask, how we can apply mathematics at all, if the trace what is counted is lost in this abstraction, in this definition of pure number? Well, here is how.

It is true that pure mathematics deals with numbers only and, of course with mathematical operations on them. We have abstracted, separated a concept of number from all possible real world objects that might have been counted. Thus, when you say 5 + 3, you right away know that the answer will be 8. No real world objects are mentioned nor even thought of when we did this addition. We just selected two numbers, and decided to do addition (we could also decide to do subtraction or multiplication). Now, how then we can apply math to real world if we don’t have a trace of what is counted? There is a way! When we want to “apply” or rather, use, math in real world, we will drag the names of objects counted into the math! We will keep track of numbers obtained, to know where they come from, which objects’ counts they represent. How we do that? We will add  a small letter, or abbreviation, or a word, name, just beside the count to tell us what we have counted. For instance, we can write numbers, 3, 5, 7, 10 after we counted (or measured) something. In order to keep track what we have counted we will add small letters right beside the numbers, like 3m, 5m, 7seconds, 10apples. Now, very important thing. These added letters do not represent math. They are for us to keep track what is counted. Unfortunately, frequently, this is all mixed up and students are often told they are doing math even when they describe what are they counted, why (to give 10 apples), where (apples from the basket, he went 3m downhill, then 5 meters uphill,), when (7seconds ago, not after). All this reasoning, descriptions, units, abbreviations, meters, seconds, apples, ago, before, after, downhill, uphill,  DO NOT BELONG TO MATH. Why is that? Because, if you look in any pure mathematical textbook or book, you will clearly see that no theorems are stated or proved by mentioning apples, meters, seconds, pears, etc. All the theorems are proved strictly in terms of mathematical objects, numbers, sets, set of numbers, using other theorems and axioms. No outside objects or descriptions, like apples, cars, downhill, uphill, will ever enter a mathematical theorem or its proof.

Now, when we distinguished what is pure math and what is applied part of it, we can make more interesting and significant conclusions. Pure mathematics deals with numbers and numbers only. Since number 3, say, can represent an abstracted count of so many, many objects, wouldn’t be interesting to have its properties investigated? It looks like there is some value in the fact that one concept, a number, stands for counts for so many objects. We can compare number 3 with other numbers. We can say which numbers are greater than or less than other numbers. We can multiply them and see what numbers we are getting. And all the time we deal only with numbers. The value is, if we get some interesting result for a certain number or numbers, from our “pure” number investigation, we can use that result for all those examples in real world. That’s the value of applied math. But, in order to use it, say, in order to use 5 + 3 = 8, we have to make a match between pure math numbers and real world counts. Hence, IF we count say, CDs and IF we get 5CDs, and, again we count another set of CDs just mentioned. This is a simple example, but there are more complex mathematical results where we don’t need to reinvent the wheel each time we get the real world count, but instead we take advantage of ready to use mathematical result, procedure, theorem, solution.

Mathematics does not see the reasoning from other worlds. Math will see number 6 (given, or picked), math will see number 10 (given, or picked), and math will see the selected, required operation, addition (it could be subtraction or division too). Does it mean that these numbers, 10 and 6 came from thin air to mathematics? They came from counting apples, but, where are the apples then? The point is, remember, when we said that numbers, in pure math, are abstraction for all the objects they can represent count of. They are not from thin air, they exist in our math as our starting point. Our pure math has already numbers available for our use, 1, 2, 3,…10, …, etc.. How? We did not even need to find objects to count to obtain different numbers. We can start with 1, then add 1 to get 2, then add 1 to get 3, etc. That’s why we have numbers already available for us. We only pick them, and do the operations. Math, for that matter, doesn’t need to know if we counted apples, or pears, of chewing gums. It is enough for math to tell there is number 10 and number 6 and that we want to add them. It is us who will keep track why we counted (because Peter was hungry),  what we counted (apples, they are edible), when we counted (in the evening, when was the time for dinner).

How we are allowed, at all, to go from non-axiomatic worlds, physics, economics, finance, to, so strictly defined, axiomatic world of mathematics? Apparently, mathematics does not care whether the problems come from axiomatized system or not! And that tells us that mathematics can not correct logical steps or see the flaws in the system it proudly claims it models. Assumptions coming from non-axiomatized fields, like physics, economics, finance, and into a strict axiomatic system, like mathematics, can produce results that can wreak havoc back in the field where the mathematics is applied.

You may ask, at this point, how we can mix these two logic worlds. One world appear to be very fluid, the real world, with objects selected, of any type, and any kind of relationships. On the other hand we have mathematical logic world, where we only deal with numbers, or sets of numbers only, and with what appears to be quite precise rules, axioms, logic, and well defined sequences of math operations (of addition, subtraction, multiplication, division). Is there a logic that will merge and connect these two worlds? YES! You can mix these two worlds, but you have to be very careful with the World # 1, the real world's objects and scenarios. Your logic there has to be correct. Then, you can use logic used to link these two worlds, and it's  is the logic already familiar to you, but with new domains of application. How it is done? Here is how. Let’s say that logical statement from the first, real world, is labelled as “p” ,  and logical statement from the second, mathematical logic world is labelled as “q”, then we can create a new, logical statement IF “p” AND “q” THEN “s”, or in shorter notation, p ^ q => s. I am sure you are familiar with this logical statement. Here is example. Let p = “Peter is hungry” and let q = “there are 10 apples”. Then we can form a statement “IF Peter is hungry and IF there are 10 apples, THEN he will get 6 apples”.

Mathematics is defined not by objects it counts, nor by reasons or logic why those objects are counted, but with concepts used to define matheatics axioms and to define proofs of mathematical theorems. 

[ applied math, applied mathematics, learn math, math applications, math concepts ]