- Basics of Computers Tutorial
- Basics of Computers – Home
- Basics of Computers – Introduction
- Basics of Computers - Classifications
- Basics of Computers – S/W Concepts
- Basics of Computers – System S/W
- Functions of Operating System
- Types of Operating System
- Basics of Computers – Utility S/W
- Open Source Software
- Basics of Computers – Office Tools
- Domain Specific Tools
- Number System
- Number System Conversion
- Microprocessor Concepts
- Evolution of Microprocessor
- Primary Memory
- Secondary Memory
- Basics of Computers – I/O Ports

- Basics of Computers Resources
- Basics of Computers – Quick Guide
- Basics of Computers – Resources
- Basics of Computers – Discussion

The technique to represent and work with numbers is called **number system**. **Decimal number system** is the most common number system. Other popular number systems include ** binary number system, octal number system, hexadecimal number system,** etc.

Decimal number system is a **base 10** number system having 10 digits from 0 to 9. This means that any numerical quantity can be represented using these 10 digits. Decimal number system is also a **positional value system**. This means that the value of digits will depend on its position. Let us take an example to understand this.

Say we have three numbers – 734, 971 and 207. The value of 7 in all three numbers is different−

- In 734, value of 7 is 7 hundreds or 700 or 7 × 100 or 7 × 10
^{2} - In 971, value of 7 is 7 tens or 70 or 7 × 10 or 7 × 10
^{1} - In 207, value 0f 7 is 7 units or 7 or 7 × 1 or 7 × 10
^{0}

The weightage of each position can be represented as follows −

In digital systems, instructions are given through electric signals; variation is done by varying the voltage of the signal. Having 10 different voltages to implement decimal number system in digital equipment is difficult. So, many number systems that are easier to implement digitally have been developed. Let’s look at them in detail.

The easiest way to vary instructions through electric signals is two-state system – on and off. On is represented as 1 and off as 0, though 0 is not actually no signal but signal at a lower voltage. The number system having just these two digits – 0 and 1 – is called **binary number system**.

Each binary digit is also called a **bit**. Binary number system is also positional value system, where each digit has a value expressed in powers of 2, as displayed here.

In any binary number, the rightmost digit is called **least significant bit (LSB)** and leftmost digit is called **most significant bit (MSB)**.

And decimal equivalent of this number is sum of product of each digit with its positional value.

11010_{2} = 1×2^{4 }+ 1×2^{3} + 0×2^{2} + 1×2^{1} + 0×2^{0}

= 16 + 8 + 0 + 2 + 0

= 26_{10}

Computer memory is measured in terms of how many bits it can store. Here is a chart for memory capacity conversion.

- 1 byte (B) = 8 bits
- 1 Kilobytes (KB) = 1024 bytes
- 1 Megabyte (MB) = 1024 KB
- 1 Gigabyte (GB) = 1024 MB
- 1 Terabyte (TB) = 1024 GB
- 1 Exabyte (EB) = 1024 PB
- 1 Zettabyte = 1024 EB
- 1 Yottabyte (YB) = 1024 ZB

**Octal number system** has eight digits – 0, 1, 2, 3, 4, 5, 6 and 7. Octal number system is also a positional value system with where each digit has its value expressed in powers of 8, as shown here −

Decimal equivalent of any octal number is sum of product of each digit with its positional value.

726_{8} = 7×8^{2 }+ 2×8^{1} + 6×8^{0}

= 448 + 16 + 6

= 470_{10}

**Octal number system** has 16 symbols – 0 to 9 and A to F where A is equal to 10, B is equal to 11 and so on till F. Hexadecimal number system is also a positional value system with where each digit has its value expressed in powers of 16, as shown here −

Decimal equivalent of any hexadecimal number is sum of product of each digit with its positional value.

27FB_{16} = 2×16^{3} + 7×16^{2} + 15×16^{1} + 10×16^{0}

= 8192 + 1792 + 240 +10

= 10234_{10}

The following table depicts the relationship between decimal, binary, octal and hexadecimal number systems.

HEXADECIMAL | DECIMAL | OCTAL | BINARY |
---|---|---|---|

0 | 0 | 0 | 0000 |

1 | 1 | 1 | 0001 |

2 | 2 | 2 | 0010 |

3 | 3 | 3 | 0011 |

4 | 4 | 4 | 0100 |

5 | 5 | 5 | 0101 |

6 | 6 | 6 | 0110 |

7 | 7 | 7 | 0111 |

8 | 8 | 10 | 1000 |

9 | 9 | 11 | 1001 |

A | 10 | 12 | 1010 |

B | 11 | 13 | 1011 |

C | 12 | 14 | 1100 |

D | 13 | 15 | 1101 |

E | 14 | 16 | 1110 |

F | 15 | 17 | 1111 |

Besides numerical data, computer must be able to handle alphabets, punctuation marks, mathematical operators, special symbols, etc. that form the complete character set of English language. The complete set of characters or symbols are called alphanumeric codes. The complete alphanumeric code typically includes −

- 26 upper case letters
- 26 lower case letters
- 10 digits
- 7 punctuation marks
- 20 to 40 special characters

Now a computer understands only numeric values, whatever the number system used. So all characters must have a numeric equivalent called the alphanumeric code. The most widely used alphanumeric code is American Standard Code for Information Interchange (ASCII). ASCII is a 7-bit code that has 128 (27) possible codes.

ISCII stands for **Indian Script Code for Information Interchange**. IISCII was developed to support Indian languages on computer. Language supported by IISCI include Devanagari, Tamil, Bangla, Gujarati, Gurmukhi, Tamil, Telugu, etc. IISCI is mostly used by government departments and before it could catch on, a new universal encoding standard called **Unicode** was introduced.

Unicode is an international coding system designed to be used with different language scripts. Each character or symbol is assigned a unique numeric value, largely within the framework of ASCII. Earlier, each script had its own encoding system, which could conflict with each other.

In contrast, this is what Unicode officially aims to do − *Unicode provides a unique number for every character, no matter what the platform, no matter what the program, no matter what the language*.

Advertisements