Looks Can Be Deceiving Essay, Research Paper Looks Can Be Deceiving Paradoxes are sometimes composed of contradictory ideas presented together, ultimately leading to an unworkable situation. Paradoxes, however, are not simply ambiguous questions. Paradoxes are the essence of the inherent complexity of systems (Internet 1).

Looks Can Be Deceiving Essay, Research Paper

Looks Can Be Deceiving

Paradoxes are sometimes composed of contradictory ideas presented together, ultimately leading to an unworkable situation. Paradoxes, however, are not simply ambiguous questions. Paradoxes are the essence of the inherent complexity of systems (Internet 1). Each paradox must be analyzed and clearly understood before it can be explained. Since mathematics is, in a sense, a universal language, certain paradoxes and contradictions have arisen that have troubled mathematicians, dating from ancient times to the present. Some are false paradoxes; that is, they do not present actual contradictions, and are merely slick logic tricks. Others have shaken the very foundations of mathematics ? requiring brilliant, creative mathematical thinking to resolve. Others remain unresolved to this day, but are assumed to be solvable. One recurring theme concerning paradoxes is that each of them can be solved to some degree of satisfaction, but are never completely conclusive. In other words, new answers will likely replace older ones, in an attempt to solidify the answer and clarify the problem.

A paradox can be defined as an unacceptable conclusion derived by apparently acceptable reasoning from apparently acceptable premises. This essay provides an introduction to a range of paradoxes and their possible solutions. In addition, a questionnaire was composed in order to demonstrate the extent of knowledge that the general population has pertaining to paradoxes.

Paradoxes are useful things, despite their mind-boggling appearance. Generally, however, most paradoxes can be ?solved? by searching for specific properties that they may contain. Therefore, if you try to describe a situation and you end up with a paradox (contradictory outcome), it usually means that the theory is wrong, or the theory or the definitions break down along the way. Also, it is possible that the situation cannot possibly occur, or the question may simply be meaningless for some other reason. Any of these possibilities are relevant, and if you exhaust all the possible interpretations, one of them should prove to be incorrect (Internet 1).

The following type of paradox is called Simpson?s Paradox. This paradox involves an apparent contradiction, because when the data are presented one way, one particular conclusion is inferred. However, when the same data are presented in another form, the opposite conclusion results.

Paradox 1:

Acceptance Percentages for College A and College

Chart 1

Section A Section B

Accepted Rejected Total Percent Accepted Accepted Rejected Total Percent Passing

Women 400 250 650 61% 50 300 350 14%

Men 50 25 75 67% 125 300 425 29%

Total 450 275 725 175 600 775

As is evident in Chart 1, when the data are presented in two separate tables, it looks as if men are accepted more often than women, because in each case (College A and College B), men are accepted at a higher ratio than women. However, when the same data are combined into one table (Chart 2), a contradicting result is implied.

Acceptance Percentage Totals for the University

Chart 2

Accepted Rejected Total Percent Accepted

Women 450 550 1000 45%

Men 175 325 500 35%

Total 625 875 1500

This table shows women actually having a higher overall acceptance rate than men. This is an example of Simpson?s Paradox because it involves misleading data. Obviously, the presentation of the data is very important, and can lead to incorrect assumptions if the data are not used properly (Internet 2).

Paradox 2:

An Arrow in Flight

One can imagine an arrow in flight, toward a target. For the arrow to reach the target, the arrow must first travel half of the overall distance from the starting point to the target. Next, the arrow must travel half of the remaining distance. For example, if the starting distance was 10m, the arrow first travels 5m, then 2.5m.

If one extends this concept further, one can imagine the resulting distances getting smaller and smaller.

Will the arrow ever reach the target? (Internet 3)

The answer is, of course, yes the arrow will reach the target. Our common sense tells us so. But, mathematically, this fact can be proven because the sum of an infinite series can be a finite number. The question contains a premise, which implies that the infinite series will result in an infinite number. Thus, 1/2 + 1/4 + 1/8 + … = 1 and the arrow hits the target (Internet 3).

Paradox 3:

Two Equals One?

Assume that

a = b. (1)

Multiplying both sides by a,

a? = ab. (2)

Subtracting b? from both sides,

a? – b? = ab – b? . (3)

Factoring both sides,

(a + b)(a – b) = b(a – b). (4)

Dividing both sides by (a – b),

a + b = b. (5)

If now we let a = 1 = b, we conclude, from step (5), that 2 = 1. Or we can subtract b from both sides and conclude that a, which can be taken as any number, must be equal to zero. Or we can substitute b for a and conclude that any number is double itself. Our result can thus be interpreted in a number of ways, all equally ridiculous.

The paradox arises from a disguised breach of the arithmetical prohibition on division by zero, occurring at Step (5). Namely, since a = b, dividing both sides by (a – b) is dividing by zero, which renders the equation meaningless. As Northrop goes on to show, the same trick can be used to prove, for example, that any two unequal numbers are equal, or that all positive whole numbers are equal (Internet 4).

Paradox 4:

Squares and Rectangles

The area of the square, shown above, is 8 x 8 = 64 units?. The square is cut in the four parts A, B, C, and D, which are rearranged into the rectangle shown below. This rectangle, however, has an area of 13 x 5 = 65 units?.

This can lead to the potential of making 65 units? of gold out of only 64 units?. How can you justify this transformation in area and the creation of matter?

The picture of the rectangle is deceptive! The line XY shown in the picture of the rectangle (see above) is not a line at all. The parts XU and VY have a gradient of 2 / 5 = 0.4, and the parts XV and UY have a gradient of 3 / 8 = 0.375. So, in fact, XUYV is a parallelogram with an area of 1, not a line!

Paradox 5:

Where Is The Missing Dollar?

Three people check into a hotel. They pay $30 to the manager and go to their room. The manager remembers that the room rate is $25 and gives $5 to the bellboy to return. On the way to the room, the bellboy reasons that $5 would be difficult to share among three people so he pockets $2 and gives $1 to each person.

Now each person paid $10 and got back $1. So they each paid $9, totaling $27. The bellboy has $2, bringing the total up to $29. Where is the missing $1?

The correct response to this question is that since all three people paid $9 each, we are looking at a total of $27. The manager has $25 for the room while the bellboy has $2 for himself. The bellboy?s $2 should be added to the manager?s $25 or subtracted from the tenant?s $27, not added to the tenant?s $27.

The existence of a paradox is proof that either, at least one of the propositions are false, or the logic used to arrive at the paradox is false, at which point you do not really have a paradox. As stated previously, there really is no such thing as a paradox, for its own existence proves that the assumptions it is based on are wrong. (Internet 5)

Searching For Answer?s

A survey was composed in order to demonstrate the extent of comprehension that the general public has in terms of paradoxes. Ten individuals, whom of which ranged from the ages 16-42, answered the questionnaires. The survey consisted of five paradoxes that were randomly chosen, each individual was given an opportunity to choose from one of three responses (yes, no, or uncertain) for each paradox. The survey showed that 32% responded yes, 16% responded no and 46% responded uncertain to the ten questions that were asked. These results justify that the individuals, who answered yes to most of the questions, were tricked by false propositions. These individuals ignored common sense and allowed themselves to be deceived. Moreover, the majority of individuals who answered no to most of the questions were aware that the paradoxes were somewhat misleading. However, they were unable to explain any further. Also, the questions that were answered with an uncertain apparently left the individuals pondering.

Survey Results In Chart Form

Number of answers which fall in each category

Individual Yes No Uncertain

Person #1 4 0 1

Person #2 3 1 1

Person #3 3 1 1

Person #4 2 2 1

Person #5 1 2 2

Person #6 2 0 3

Person #7 3 0 2

Person #8 0 1 4

Person #9 0 0 5

Person #10 1 1 3

Total 19/50 8/50 23/50

Percentages 38% 16% 46%

Survey Results Represented On A Pie Graph

Conclusion

Paradoxes

Survey

Question 1:

Acceptance Percentages for College A and College B

College A College B

Accepted Rejected Total Percent Accepted Accepted Rejected Total Percent Passing

Women 400 250 650 61% 50 300 350 14%

Men 50 25 75 67% 125 300 425 29%

Total 450 275 725 175 600 775

Do the women have reason to claim sexual discrimination against the university?

a) Yes. Explain:

b) No. Explain:

c) Uncertain

Question 2:

An Arrow In Flight

One can imagine an arrow in flight, toward a target. For the arrow to reach the target, the arrow must first travel half of the overall distance from the starting point to the target. Next, the arrow must travel half of the remaining distance. For example, if the starting distance was 10m, the arrow first travels 5m, then 2.5m.

If one extends this concept further, one can imagine the resulting distances getting smaller and smaller.

Will the arrow ever reach the target? (2)

a) Yes. Explain:

b) No. Explain:

c) Uncertain

Question 3:

Does Two Equal One?

Assume that

a = b. (1)

Multiplying both sides by a,

a? = ab. (2)

Subtracting b? from both sides,

a? – b? = ab – b?. (3)

Factoring both sides,

(a + b)(a – b) = b(a – b). (4)

Dividing both sides by (a – b),

a + b = b. (5)

Let a=1=b,

2=1.

Do you agree?

a) Yes. Explain:

b) No. Explain:

c) Uncertain.

Question 4:

Squares and Rectangles

The area of the square, shown above, is 8 x 8 = 64 units?. The square is cut in the four parts A, B, C, and D, which are rearranged into the rectangle shown below. This rectangle, however, has an area of 13 x 5 = 65 units?.

This can lead to the potential of making 65 units? of gold out of only 64 units?. Is this a valid transformation in area?

a) Yes. Explain:

b) No. Explain:

c) Uncertain

Question 5

The Missing Dollar

Three people check into a hotel. They pay $30 to the manager and go to their room. The manager remembers that the room rate is $25 and gives $5 to the bellboy to return. On the way to the room, the bellboy reasons that $5 would be difficult to share among three people so he pockets $2 and gives $1 to each person.

Now each person paid $10 and got back $1. So they each paid $9, totaling $27. The bellboy has $2, bringing the total up to $29. Is a dollar missing?

a) Yes. Explain:

b) No. Explain:

c) Uncertain.

Work Cited

(Internet 1) http://www.colchsfe.ac.uk/