Number Play Class 7 Notes Maths Chapter 6

Class 7 Maths Chapter 6 Notes Number Play

Class 7 Maths Notes Chapter 6 – Class 7 Number Play Notes

→ In the first activity, we saw how to represent information about how a sequence of numbers (e.g., height measures) is arranged without knowing the actual numbers.

→ We learnt the notion of parity — numbers that can be arranged in pairs (even numbers) and numbers that cannot be arranged in pairs (odd numbers).

→ We learnt how to determine the parity of sums and products.

→ While exploring sums in grids, we could determine whether filling a grid is impossible by looking at the row and column sums. We extended this to construct magic squares.

→ We saw how Virahanka numbers were first discovered in history through the Arts. The Virahanka sequence is 1, 2, 3, 5, 8, 13, 21, 34, 55, …

→ We became math detectives through cryptarithms, where letters replace digits.

Numbers Tell Us Things Class 7 Notes

What do the numbers in the figure below tell us?
Remember the children from the Grade 6 mathematics?
Now, they call out numbers using a different rule.

What do you think these numbers mean?
The children rearrange themselves, and each one says a number based on the new arrangement.

Could you figure out what these numbers convey? Observe and try to find out.
The rule is — each child calls out the number of children in front of them who are taller than they are. Check if the number each child says matches this rule in both arrangements.

Picking Parity Class 7 Notes

Kishor has some number cards and is working on a puzzle: There are 5 boxes, and each box should contain exactly 1 number card. The numbers in the boxes should sum to 30. Can you help him find a way to do it?

Can you figure out which 5 cards add to 30? Is it possible?
There are many ways of choosing 5 cards from this collection.
Is there a way to find a solution without checking all possibilities?
Let us find out.

Add a few even numbers together. What kind of number do you get?
Does it matter how many numbers are added?
Any even number can be arranged in pairs without any leftovers.
Some even numbers are shown here, arranged in pairs.

As we see in the figure, adding any number of even numbers will result in a number that can still be arranged in pairs without any leftovers. In other words, the sum will always be an even number.

Now, add a few odd numbers together. What kind of number do you get? Does it matter how many odd numbers are added?
Odd numbers can not be arranged in pairs. An odd number is one more than a collection of pairs. Some odd numbers are shown below:

Can we also think of an odd number as one less than a collection of pairs?

This figure shows that the sum of two odd numbers must always be even! This, along with the other figures her,e are more examples of a proof!

Let us go back to the puzzle Kishor was trying to solve. There are 5 empty boxes. That means he has an odd number of boxes. All the number cards contain odd numbers. They should add to 30, which is an even number. Since adding any 5 odd numbers will never result in an even number, Kishor cannot arrange these cards in the boxes to add up to 30.

Two siblings, Martin and Maria, were born exactly one year apart. Today they are celebrating their birthday. Maria exclaims that the sum of their ages is 112. Is this possible? Why or why not?

As they were born one year apart, their ages will be (two) consecutive numbers. Can their ages be 51 and 52? 51 + 52 = 103. Try some other consecutive numbers and see if their sum is 112.

The counting numbers 1, 2, 3, 4, 5, … alternate between even and odd numbers. In any two consecutive numbers, one will always be even and the other will always be odd!

What would be the resulting sum of an even number and an odd number? We can see that their sum can’t be arranged in pairs and thus will be an odd number.

Since 112 is an even number, and Martin’s and Maria’s ages are consecutive numbers, they cannot add up to 112. We use the word parity to denote the property of being even or odd.

For instance, the parity of the sum of any two consecutive numbers is odd. Similarly, the parity of the sum of any two odd numbers is even.

Small Squares in Grids
In a 3 × 3 grid, there are 9 small squares, which is an odd number. Meanwhile, in a 3 × 4 grid, there are 12 small squares, which is an even number.

Parity of Expressions
Consider the algebraic expression: 3n + 4. For different values of n, the expression has different parity:

Come up with an expression that always has even parity.
Some examples are: 100p and 48w – 2. Try to find more.

Come up with expressions that always have odd parity.

Come up with other expressions, like 3n + 4, which could have either odd or even parity.

The expression 6k + 2 evaluates to 8, 14, 20,… (for k = 1, 2, 3,…) — many even numbers are missing.

Are there expressions that we can use to list all the even numbers?
Hint: All even numbers have a factor of 2.

Are there expressions that we can use to list all odd numbers?

We saw earlier how to express the nth term of the sequence of multiples of 4, where n is the letter-number that denotes a position in the sequence (e.g., first, twenty-third, hundred and seventeenth, etc.).

What would be the nth term for multiples of 2? Or, what is the nth even number?
Let us consider odd numbers.

What is the 100th odd number?
To answer this question, consider the following question:

What is the 100th even number?
This is 2 × 100 = 200.
Does this help in finding the 100th odd number?
Let us compare the sequence of even and odd terms term-by-term.
Even Numbers: 2, 4, 6, 8, 10, 12,…
Odd Numbers: 1, 3, 5, 7, 9, 11,…

We see that at any position, the value in the odd-number sequence is one less than that in the even-number sequence. Thus, the 100th odd number is 200 – 1 = 199.

Write a formula to find the nth odd number.
Let us first describe the method that we have learnt to find the odd number at a given position:
(a) Find the even number at that position. This is 2 times the position number.
(b) Then subtract 1 from the even number.

Writing this in expressions, we get
(a) 2n
(b) 2n – 1
Thus, 2n is the formula that gives the nth even number, and 2n – 1 is the formula that gives the nth odd number.

Some Explorations in Grids Class 7 Notes

Observe this 3 × 3 grid. It is filed following a simple rule — use numbers from 1 – 9 without repeating any of them. There are circled numbers outside the grid.

Are you able to see what the circled numbers represent?
The numbers in the yellow circles are the sums of the corresponding rows and columns.
Fill the grids below based on the rule mentioned above:

You might have realised that it is not possible to find a solution for this grid. Why is this the case?

The smallest sum possible is 6 = 1 + 2 + 3. The largest sum possible is 24 = 9 + 8 + 7. Any number in a circle cannot be less than 6 or greater than 24. The grid has sums 5 and 26. Therefore, this is impossible!

In the earlier grids that we solved, Kishor noticed that the sum of all the numbers in the circles was always 90. Also, Vidya observed that the sum of the circled numbers for all three rows, or for all three columns, was always 45. Check if this is true in the previous grids you have solved.

Why should the row sums and column sums always add to 45?
From this grid, we can see that all the row sums added together will be the same as the sum of the numbers 1 – 9.
This can be seen for column sums as well.
The sum of the numbers 1 – 9 is 1 + 2 + 3 + 4 + 5 + 6 + 7 + 8 + 9 = 45.

A square grid of numbers is called a magic square if each row, each column, and each diagonal adds up to the same number. This number is called the magic sum. Diagonals are shown in the picture.

Trying to create a magic square by randomly filling the grid with numbers may be difficult! This is because there are a large number of ways of filling a 3 × 3 grid using the numbers 1 – 9 without repetition. It can be found that there are exactly 3,62,880 such ways. Surprisingly, the number of ways to fill in the grid can be found without listing all of them. We will see in later years how to do this.

Instead, we should proceed systematically to make a magic square. For this, let us ask ourselves some questions.

1. What can the magic sum be? Can it be any number?

Let us focus, for the moment, only on the row sums. We have seen that in a 3 × 3 grid with numbers 1 – 9, the total of row sums will always be 45.
Since in a magic square the row sums are all equal, and they add up to 45, they have to be 15 each. Thus, we have the following observation.

Observation 1: In a magic square made using the numbers 1 – 9, the magic sum must be 15.

2. What are the possible numbers that could occur at the centre of a magic square?

Let us consider the possibilities one by one.
Can the central number be 9? If yes, then 8 must come in one of the other squares.
For example, in this, we must have 8 + 9 + other numbers = 15. But this is not possible!
The same issue will occur no matter where we place 8. So, 9 cannot be at the centre. Can the central number be 1?

If yes, then 2 should come in one of the other squares.
Here, we must have 2 + 1 + other numbers = 15. But this is not possible because we are only using the numbers 1 – 9.
The same issue will occur no matter where we place 1. So, 1 cannot be at the centre, either.

Using such reasoning, find out which other numbers 1 – 9 cannot occur at the centre. This exploration will lead us to the following interesting observation.

Observation 2: The number occurring at the centre of a magic square, filled using 1 – 9, must be 5.

Let us now see where the smallest number 1 and the largest number 9 should come in a magic square.
Our second observation tells us that they will have to come in one of the boundary positions. Let us classify these positions into two categories:

Can 1 occur in a corner position? For example, can it be placed as follows?
If yes, then there should exist three ways of adding 1 to two other numbers to give 15.
We have 1 + 5 + 9 = 1 + 6 + 8 = 15. Is any other combination possible?

Similarly, can 9 can be placed in a corner position?

Observation 3: The numbers 1 and 9 cannot occur in any corner, so they should occur in one of the middle positions.

Can you find the other possible positions for 1 and 9?

Now, we have one full row or column of the magic square!
Try completing it!
[Hint: First fill the row or columns containing 1 and 9]

Generalising a 3 × 3 Magic Square
We can describe how the numbers within the magic square are related to each other, i.e., the structure of the magic square.

Choose any magic square that you have made so far using consecutive numbers. If m is the letter-number of the number in the centre, express how other numbers are related to m, how much more or less than m.
[Hint: Remember how we described a 2 × 2 grid of a calendar month in the Algebraic Expressions chapter].

Once the generalised form is obtained, share your observations with the class.

The First-ever 4 × 4 Magic Square
The first ever recorded 4 × 4 magic square is found in a 10th-century inscription at the Parshvanath Jain temple in Khajuraho, India, and is known as the Chautisa Yantra.

The first ever recorded 4 × 4 magic square, the Chautisa Yantra, at Khajuraho, India
Chautis means 34. Why do you think they called it the Chautisa Yantra?
Every row, column, and diagonal in this magic square adds up to 34.
Can you find other patterns of four numbers in the square that add up to 34?

Magic Squares in History and Culture
The first magic square ever recorded, the Lo Shu Square, dates back over 2000 years to ancient China. The legend tells of a catastrophic flood on the Lo River, during which the gods sent a turtle to save the people. The turtle carried a 3 × 3 grid on its back, with the numbers 1 to 9 arranged in a magical pattern.

Magic squares were studied in different parts of the world at different points in time, including India, Japan, Central Asia, and Europe.

Indian mathematicians have worked extensively on magic squares, describing general methods of constructing them. The work of Indian mathematicians was not just limited to 3 × 3 and 4 × 4 grids, which we considered above, but also extended to 5 × 5 and other larger square grids. We shall learn more about these in later grades.

The occurrence of magic squares is not limited to scholarly mathematical works. They are found in many places in India. The picture to the right is of a 3 × 3 magic square found on a pillar in a temple in Palani, Tamil Nadu. The temple dates back to the 8th century CE.

3 × 3 magic squares can also be found in homes and shops in India. The Navagraha Yantra is one such example shown below.

Notice that a different magic sum is associated with each graha. A picture of a Kubera Yantra is shown below:

Nature’s Favourite Sequence: The Virahanka–Fibonacci Numbers! Class 7 Notes

The sequence 1, 2, 3, 5, 8, 13, 21, 34,… (Virahanka–Fibonacci Numbers) is one of the most celebrated sequences in all of mathematics — it occurs throughout the world of Art, Science, and Mathematics. Even though these numbers are found very frequently in Science, it is remarkable that these numbers were first discovered in the context of Art (specifically, poetry)! The Virahanka–Fibonacci Numbers thus provide a beautiful illustration of the close links between Art, Science, and Mathematics.

Discovery of the Virahanka Numbers
The Virahanka numbers first came up thousands of years ago in the works of Sanskrit and Prakrit linguists in their study of poetry!

In the poetry of many Indian languages, including Prakrit, Sanskrit, Marathi, Malayalam, Tamil, and Telugu, each syllable is classified as either long or short.

A long syllable is pronounced for a longer duration than a short syllable — in fact, for exactly twice as long. When singing such a poem, a short syllable lasts one beat of time, and a long syllable lasts two beats of time.

This leads to numerous mathematical questions, which the ancient poets in these languages considered extensively. Several important mathematical discoveries were made in the process of asking and answering these questions about poetry.

One of these particularly important questions was the following.
How many rhythms are there with 8 beats consisting of short syllables (1 beat) and long syllables (2 beats)? That is, in how many ways can one fill 8 beats with short and long syllables, where a short syllable takes one beat of time and a long syllable takes two beats of time. Here are some possibilities:

• long long long long
• short short short short short short short short
• short long long short long
• long long short short long
  .
  .
  .

Can you find others?
Phrased more mathematically: In how many different ways can one write a number, say 8, as a sum of 1’s and 2’s?
For example, we have:
8 = 2 + 2 + 2 + 2,
8 = 1 + 1 + 1 + 1 + 1 + 1 + 1 + 1,
8 = 1 + 2 + 2 + 1 + 2,
8 = 2 + 2 + 1 + 1 + 2, etc.

Do you see other ways?
Here are all the ways of writing each of the numbers 1, 2, 3, and 4, as the sum of 1’ s and 2’ s.

Try writing the number 5 as a sum of 1s and 2s in all possible ways in your notebook! How many ways did you find? (You should find 8 different ways!)
Can you figure out the answer without listing down all the possibilities? Can you try it for n = 8?

Here is a systematic way to write down all rhythms of short and long syllables having 5 beats. Write a ‘1+’ in front of all rhythms having 4 beats, and then a ‘2+’ in front of all rhythms having 3 beats. This gives us all the rhythms having 5 beats:

Thus, 8 rhythms have 5 beats!

The reason this method works is that every 5-beat rhythm must begin with either a ‘1+’ or a ‘2+’. If it begins with a ‘1+’, then the remaining numbers must give a 4-beat rhythm, and we can write all those down.

If it begins with a 2+, then the remaining number must give a 3-beat rhythm, and we can write all those down. Therefore, the number of 5-beat rhythms is the number of 4-beat rhythms, plus the number of 3-beat rhythms.

How many 6-beat rhythms are there? By the same reasoning, it will be the number of 5-beat rhythms plus the number of 4-beat rhythms, i.e., 8 + 5 = 13. Thus, 13 rhythms have 6 beats.

Use the systematic method to write down all 6-beat rhythms, i.e., write 6 as the sum of 1’s and 2’s in all possible ways. Did you get 13 ways?
This beautiful method for counting all the rhythms of short syllables and long syllables having any given number of beats was first given by the great Prakrit scholar Virahanka around the year 700 CE. He gave his method in the form of a Prakrit poem! For this reason, the sequence 1, 2, 3, 5, 8, 13, 21, 34,… is known as the Virahanka sequence, and the numbers in the sequence are known as the Virahanka numbers. Virahanka was the first known person in history to explicitly consider these important numbers and write down the rule for their formation.

Other scholars in India also considered these numbers in the same poetic context. Virahanka was inspired by the earlier work of the legendary Sanskrit scholar Pingala, who lived around 300 BCE. After Virahanka, these numbers were also written about by Gopala (c. 1135 CE) and then by Hemachandra (c. 1150 CE).

In the West, these numbers have been known as the Fibonacci numbers, after the Italian mathematician who wrote about them in the year 1202 CE — about 500 years after Virahanka. As we can see, Fibonacci was not the first, nor the second, nor even the third person to write about these numbers! Sometimes the term “Virahanka–Fibonacci numbers” is used so that everyone understands what is being referred to.

So, how many rhythms of short and long syllables are there having 8 beats?
We simply take the 8th element of the Virahanka sequence: 1, 2, 3, 5, 8, 13, 21, 34, 55, ….. Thus, 34 rhythms have 8 beats.

Write the next number in the sequence after 55.
We have seen that the next number in the sequence is given by adding the two previous numbers. Check that this holds for the numbers given above. The next number is 34 + 55 = 89.

Write the next 3 numbers in the sequence:
1, 2, 3, 5, 8, 13, 21, 34, 55, 89, ____, ____, ____, …
If you have to write one more number in the sequence above, can you tell whether it will be an odd number or an even number (without adding the two previous numbers)?

What is the parity of each number in the sequence? Do you notice any pattern in the sequence of parities?
Today, the Virahanka–Fibonacci numbers form the basis of many mathematical and artistic theories, from poetry to drumming, to visual arts and architecture, to science. Perhaps the most stunning occurrences of these numbers are in nature. For example, the number of petals on a daisy is generally a Virahanka number.

How many petals do you see on each of these flowers?

There are many other remarkable mathematical properties of the Virahanka–Fibonacci numbers that we will see later, in mathematics as well as in other subjects. These numbers truly exemplify the close connections between Art, Science, and Mathematics.

Digits in Disguise Class 7 Notes

You have done arithmetic operations with numbers. How about doing the same with letters?
In the calculations below, digits are replaced by letters. Each letter stands for a particular digit (0 – 9). You have to figure out which digit each letter stands for.

Here, we have a one-digit number that, when added to itself twice, gives a 2-digit sum. The unit’s digit of the sum is the same as the single digit being added.

What could U and T be? Can T be 2? Can it be 3?
Once you explore, you will see that T = 5 and UT = 15.

Let us look at one more example shown on the right.
Here, K2 means that the number is a 2-digit number having the digit ‘2’ in the units place and ‘K’ in the tens place. K2 is added to itself to give a 3-digit sum HMM.

What digit should the letter M correspond to?
Both the tens place and the units place of the sum have the same digit.

What about H? Can it be 2? Can it be 3?
These types of questions can be interesting and fun to solve! Here are some more questions like this for you to try out. Find out what each letter stands for.
Share how you thought about each question with your classmates; you may find some new approaches.

These types of questions are called ‘cryptarithms’ or ‘alphametics’.

Class 7 Maths Notes

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