Secrets of Mental Math by Arthur Benjamin (reading fiction .TXT) π
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- Author: Arthur Benjamin
Read book online Β«Secrets of Mental Math by Arthur Benjamin (reading fiction .TXT) πΒ». Author - Arthur Benjamin
Next have someone add the four numbers and announce the total. Then have someone open the envelope to reveal your prediction. Take a bow!
Why This Trick Works
Look at the numbers in each set of cards and see if you can find anything consistent about them. Each set of numbers sums to the same total. Set A numbers total to 20. Set B numbers total to 23. Set C numbers total to 17. With person Cβs numbers in the right column totaling to 17, you will always put down the 7 and carry the 1. With person Bβs numbers totaling to 23, plus the 1, you will always put down the 4 and carry the 2. Finally with person Aβs numbers totaling to 20, adding the 2 gives you a total of 2247!
A DAY FOR ANY DATE
We conclude our book with one of the classic feats of mental calculation: how to figure out the day of the week of anyoneβs birthday. This is actually a very practical skill. Itβs not every day that someone will ask you to square a three-digit number, but hardly a day goes by without somebody mentioning a date to you in the past or future. With just a little bit of practice, you can quickly and easily determine the day of the week of practically any date in history.
First we assign a code number to every day of the week. They are easy to remember:
I have found the above list to be easy to remember, especially since 2βs day is Tuesday. The other days can be given similar mnemonics: β1 day is Monday, 4βs day is Thursday, and 5 day is Friday. For Wednesday, notice that if you hold up three fingers, you get the letter w. For the weekends (at the end of our list), you might think of Saturday as 6-urday and Sunday as 7 day (especially if you pronounce the ? softly). Or to remember the zero, you could think of Sunday as none-day or nun-day!
Next we need a code for every month of the year. These month codes are used for every year, with two exceptions. In a leap year (like 2000 or 2004 or 2008 or β¦) the month code for January is 5, and the month code for February is 1. To make the month codes easier to remember, we provide a table of mnemonics below.
Now letβs calculate the day of the week for any date in 2006. After that, we will describe 2007, then 2008, and so on, for the rest of your life. Once all future dates are taken care of, we can look back into the past and determine the days of the week for any date in the 1900s or any other century.
Every year is assigned a code number, and for 2006 that year code happens to be 0 (see this page).
Now, to calculate the day of the week, you simply add the month code plus the date code plus the year code. Thus for December 3, 2006, we compute
Month Code + Date + Year Code = 4 + 3 + 0 = 7
Hence, this date will be on Day 7, which is Sunday.
How about November 18, 2006? Since November has a month code of 2, we have
Month Code + Date + Year Code = 2 + 18 + 0 = 20.
Now since the week repeats every seven days, we can subtract any multiple of 7 from our answer (7, 14, 21, 28, 35, β¦) and this will not change the day of the week. So our final step is to subtract the biggest multiple of 7 to get 20 β 14 = 6. Hence November 18, 2006, occurs on Saturday.
How about 2007? Well, what happens to your birthday as you go from one year to the next? For most years, there are 365 days, and since 364 is a multiple of 7 (7 Γ 52 = 364), then the day of the week of your birthday will shift forward by one day in most years. If there are 366 days between your birthdays, then it will shift forward by two days. Hence, for 2007 we calculate the day of the week just as before, but now we use a year code of 1. Next, 2008 is a leap year. (Leap years occur every four years, so 2000, 2004, 2008, 2012, β¦, 2096 are the leap years of the twenty-first century.) Hence, for 2008, the year code increases by two, so it will have a year code of 3. The next year, 2009, is not a leap year, so the year code increases by one, to 4.
Thus, for example, May 2, 2007, has
Month Code + Date + Year Code = 0 + 2 + 1=3
so this date is a Wednesday.
For September 9, 2008, we have
Month Code + Date + Year Code = 4 + 9 + 3= 16
Subtracting the biggest multiple of 7, we have 16 β 14 = 2, so this date is a Tuesday.
On the other hand, January 16, 2008, is a leap year January, so its month code will be 5 instead of 6. Thus, we have
Month Code + Date + Year Code = 5 + 16 + 3 = 24
and therefore occurs on day 24 β 21 = 3, which is Wednesday. For your reference, we have listed all of the year codes for the twenty-first century in the figure on the following page.
The good news is that we do not have to memorize this table. We can mentally calculate the year code for any date between 2000 and 2099. For the year code of 2000 + x, we simply take the number x/4 (ignoring any remainder) and add that to x. The year code can be reduced by subtracting any multiple of 7.
For example, with 2061, we see that = 15 (with a remainder of 1 that we ignore). Thus 2061 has a year code of 61 + 15 = 76. And since we can subtract any multiple of 7, we use the simpler year code of 76 β 70 = 6.
Hence March 19, 2061, has
Month Code + Date + Year Code = 2 + 19 + 6 = 27
Subtracting 27 β 21 = 6 tells us that this date will take place on Saturday.
What about birth dates between 1900 and 1999? Do the problem exactly as in the previous calculation, but shift the final answer forward by one day (or simply add 1 to the year code). Thus March 19, 1961, occurred on a Sunday.
For the date December 3, 1998, we have = 24 (with a remainder of 2 that we ignore). Thus 1998 has year code 98 + 24 + 1 = 123, where the plus one is added for dates in the 1900s. Next, subtract the biggest multiple of 7. For handy reference, here are the multiples of 7 that you might need:
7, 14, 21, 28, 35, 42, 49, 56, 63, 70, 77, 84, 91, 98, 105, 112, 119, 126, β¦
Since 123 β 119 = 4, 1998 has a year code of 4. Therefore, December 3, 1998, has
Month Code + Date + Year Code = 4 + 3 + 4 = 11
and 11 β 7 = 4, so this date occurred on a Thursday.
For dates in the 1800s, we add 3 to the year code. For example, Charles Darwin and Abraham Lincoln were both born on February 12, 1809. Since 2009 has a year code of 4, then 1809 has a year code of 4 + 3 = 7, which can be reduced to 0. Thus, February 12, 1809, has
Month Code + Date + Year Code = 2 + 12 + 0= 14
and 14 β 14 = 0, so they were both born on a Sunday.
For dates in the 2100s, we add 5 to the year code (or, equivalently, subtract 2 from the year code). For example, since 2009 has a year code of 4, then 2109 has a year code of 4 + 5 = 9, which, after subtracting 7 is the same as a year code of 2. Dates in the 1700s are treated just like in the 2100s (by adding 5 or subtracting 2) but we need to be careful. The days that we are calculating are based on the Gregorian calendar, established in 1582. But this calendar was not adopted by England (and the American colonies) until 1752, when Wednesday, September 2, was followed by Thursday, September 14. Letβs verify that September 14, 1752, was indeed a Thursday. Since 2052 has a year code of 2 (from this page, or by 52 + 13 β 63 = 2), then 1752 has a year code of 0. Thus September 14, 1752, has
Month Code + Date + Year Code = 4 + 14 + 0= 18
and 18 β 14 = 4, so it was indeed a Thursday. However, our formula will not work for earlier dates (which were governed by the Julian calendar).
Finally, we remark that under the Gregorian calendar, a leap year occurs every four years, with the exception of years that are divisible by 100, although there is an exception to the exception: years divisible by 400 are leap years. Thus 1600, 2000, 2400, and 2800 are leap years, but 1700, 1800, 1900, 2100, 2200, 2300, and 2500 are not leap years. In fact, the Gregorian calendar repeats every 400 years, so you can convert any future date into a date near 2000. For example, March 19, 2361, and March 19, 2761, will have the same day of the week as March 19, 1961, which, as we already determined, is a Sunday.
Determine the days of the week for the following dates:
1. January 19, 2007
2. February 14, 2012
3. June 20, 1993
4. September 1, 1983
5. September 8, 1954
6. November 19, 1863
7. July 4, 1776
8. February 22, 2222
9. June 31, 2468
10. January 1, 2358
*In a leap year, the code for January is 5 and the code for February is 1.
Chapter β Epilogue by Michael Shermer: How Math Helps Us Think About Weird ThingsChapter β
Epilogue: How Math Helps Us Think About Weird Things
by Michael Shermer
As the publisher of Skeptic magazine, the executive director of the Skeptics Society, and a Scientific American editor with a monthly column entitled βSkeptic,β I receive volumes of mail from people who challenge me with stories about their unusual experiences, such as haunted houses, ghosts, near-death and out-of-body experiences, UFO sightings, alien abductions, death-premonition dreams, and much more.
The most interesting stories to me are those about highly improbable events. The implication of the letter writerβs tale is that if I cannot offer a satisfactory natural explanation for that particular event, the general principle of supernaturalism is preserved. A common story is the one about having a dream about the death of a friend or relative, then a phone call comes the next day about the unexpected death of the person in the dream. What are the odds of that? I am asked.
Here is where math comes in to play in our
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