Contributors: Shawn Hymel
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Introduction
If computers operate in binary, then how are we able to store letters and words? To do this, we assign numbers to characters. This is known as character encoding.
Looking at the internals of a simple text document
To understand how character encoding works, let's create a simple example. First, assign the numbers 1-26 to the English alphabet:
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26a b c d e f g h i j k l m n o p q r s t u v w x y zTo write a simple encoded message, we substitute the numbers for the letters. For example, 8 5 12 12 15. By using numbers, we have constructed the word h e l l o.
But to completely capture the English alphabet -- including upper and lower-case letters, numbers, and punctuation -- we needed more than 26 characters. As a result, the American Standard Code for Information Interchange (ASCII) was created as one of the first character encoding standards for computers.
What You Will Learn
The following topics will be covered in this tutorial:
- A brief history of ASCII
- How to translate decimal, binary, and hexadecimal numbers to ASCII
Suggested Reading
There are a few concepts that you might want to be familiar with before starting to read this guide:
- Binary - Knowing how a computer stores numbers is useful to translating those numbers to characters.
- Hexadecimal - Hexadecimal is often used to express binary numbers in groups of 4 bits.
- Installing Arduino IDE - Arduino is a good way to try printing ASCII characters.
History
The American Standards Association (ASA), now the American National Standards Institute (ANSI), began work on ASCII on October 6, 1960. The encoding scheme had origins in the 5-bit telegraph codes invented by Émile Baudot. The committee eventually decided on a 7-bit code for ASCII.
7 bits allow for 128 characters. While only American English characters and symbols were chosen for this encoding set, 7 bits meant minimized costs associated with transmitting this data (as opposed to say, 8 bits).
The first 32 characters of ASCII were reserved control characters. These characters were used to relay special instructions to other devices, like printers. For example, a user could advance a line, delete a character, and on some devices, ring a bell (such as on the Teletype Model 33 ASR).
ASA published the first version of ASCII in 1963 and revised it in 1967. The last major update to the standard occurred in 1986. ASCII first saw commercial use in the American Telephone & Telegraph (AT&T) TeletypeWriter Exchange (TWX) network.
Teleprinters, like this Teletype Model 33 ASR, were used to send typed messages to one or more other teleprinters across various communication channels (Image courtesy of Arnold Reinhold of Wikimedia Commons)
On March 11, 1968 President Lyndon B. Johnson mandated that all US federal government computers must support ASCII, thus cementing ASCII's place in American computing history.
Other encoding schemes existed at the time, such as the International Telegraph Alphabet No. 2 (ITA2), but ASCII quickly became the standard for American English encoding. ASCII was the most common encoding found on the Internet until it was surpassed by UTF-8 in 2007.
ASCII Table
To identify a character's ASCII value, it is common to look it up on an ASCII table. The ASCII table pairs each character to its assigned value between 0 and 127.
Control Characters
Control characters make up the first 32 characters of the ASCII table. These characters are not intended to be printed, instead they are used to send command instructions to another device, such as a printer. Note that we have included the octal representation of the ASCII characters in the off chance that you might be working with a particularly old system (such as the 12-bit PDP-8).
| Dec | Bin | Oct | Hex | Char | Description |
|---|---|---|---|---|---|
| 0 | 0000 0000 | 000 | 00 | NUL | null |
| 1 | 0000 0001 | 001 | 01 | SOH | start of heading |
| 2 | 0000 0010 | 002 | 02 | STX | start of text |
| 3 | 0000 0011 | 003 | 03 | ETX | end of text |
| 4 | 0000 0100 | 004 | 04 | EOT | end of transmission |
| 5 | 0000 0101 | 005 | 05 | ENQ | enquiry |
| 6 | 0000 0110 | 006 | 06 | ACK | acknowledge |
| 7 | 0000 0111 | 007 | 07 | BEL | bell |
| 8 | 0000 1000 | 010 | 08 | BS | backspace |
| 9 | 0000 1001 | 011 | 09 | TAB | horizontal tab |
| 10 | 0000 1010 | 012 | 0A | LF | line feed, new line |
| 11 | 0000 1011 | 013 | 0B | VT | vertical tab |
| 12 | 0000 1100 | 014 | 0C | FF | form feed, new page |
| 13 | 0000 1101 | 015 | 0D | CR | carriage return |
| 14 | 0000 1110 | 016 | 0E | SO | shift out |
| 15 | 0000 1111 | 017 | 0F | SI | shift in |
| 16 | 0001 0000 | 020 | 10 | DLE | data link escape |
| 17 | 0001 0001 | 021 | 11 | DC1 | device control 1 |
| 18 | 0001 0010 | 022 | 12 | DC2 | device control 2 |
| 19 | 0001 0011 | 023 | 13 | DC3 | device control 3 |
| 20 | 0001 0100 | 024 | 14 | DC4 | device control 4 |
| 21 | 0001 0101 | 025 | 15 | NAK | negative acknowledge |
| 22 | 0001 0110 | 026 | 16 | SYN | synchronous idle |
| 23 | 0001 0111 | 027 | 17 | ETB | end of transmission block |
| 24 | 0001 1000 | 030 | 18 | CAN | cancel |
| 25 | 0001 1001 | 031 | 19 | EM | end of medium |
| 26 | 0001 1010 | 032 | 1A | SUB | substitute |
| 27 | 0001 1011 | 033 | 1B | ESC | escape |
| 28 | 0001 1100 | 034 | 1C | FS | file separator |
| 29 | 0001 1101 | 035 | 1D | GS | group separator |
| 30 | 0001 1110 | 036 | 1E | RS | record separator |
| 31 | 0001 1111 | 037 | 1F | US | unit separator |
| 127 | 0111 1111 | 177 | 7F | DEL | delete |
Printable Characters
There are 95 printable characters in the ASCII encoding scheme. Note that the "space" character denotes a printable space (" ").
| Dec | Bin | Oct | Hex | Char |
|---|---|---|---|---|
| 32 | 0010 0000 | 040 | 20 | space |
| 33 | 0010 0001 | 041 | 21 | ! |
| 34 | 0010 0010 | 042 | 22 | " |
| 35 | 0010 0011 | 043 | 23 | # |
| 36 | 0010 0100 | 044 | 24 | $ |
| 37 | 0010 0101 | 045 | 25 | % |
| 38 | 0010 0110 | 046 | 26 | & |
| 39 | 0010 0111 | 047 | 27 | ' |
| 40 | 0010 1000 | 050 | 28 | ( |
| 41 | 0010 1001 | 051 | 29 | ) |
| 42 | 0010 1010 | 052 | 2A | * |
| 43 | 0010 1011 | 053 | 2B | + |
| 44 | 0010 1100 | 054 | 2C | , |
| 45 | 0010 1101 | 055 | 2D | - |
| 46 | 0010 1110 | 056 | 2E | . |
| 47 | 0010 1111 | 057 | 2F | / |
| 48 | 0011 0000 | 060 | 30 | 0 |
| 49 | 0011 0001 | 061 | 31 | 1 |
| 50 | 0011 0010 | 062 | 32 | 2 |
| 51 | 0011 0011 | 063 | 33 | 3 |
| 52 | 0011 0100 | 064 | 34 | 4 |
| 53 | 0011 0101 | 065 | 35 | 5 |
| 54 | 0011 0110 | 066 | 36 | 6 |
| 55 | 0011 0111 | 067 | 37 | 7 |
| 56 | 0011 1000 | 070 | 38 | 8 |
| 57 | 0011 1001 | 071 | 39 | 9 |
| 58 | 0011 1010 | 072 | 3A | : |
| 59 | 0011 1011 | 073 | 3B | ; |
| 60 | 0011 1100 | 074 | 3C | < |
| 61 | 0011 1101 | 075 | 3D | = |
| 62 | 0011 1110 | 076 | 3E | > |
| 63 | 0011 1111 | 077 | 3F | ? |
| Dec | Bin | Oct | Hex | Char |
|---|---|---|---|---|
| 64 | 0100 0000 | 100 | 40 | @ |
| 65 | 0100 0001 | 101 | 41 | A |
| 66 | 0100 0010 | 102 | 42 | B |
| 67 | 0100 0011 | 103 | 43 | C |
| 68 | 0100 0100 | 104 | 44 | D |
| 69 | 0100 0101 | 105 | 45 | E |
| 70 | 0100 0110 | 106 | 46 | F |
| 71 | 0100 0111 | 107 | 47 | G |
| 72 | 0100 1000 | 110 | 48 | H |
| 73 | 0100 1001 | 111 | 49 | I |
| 74 | 0100 1010 | 112 | 4A | J |
| 75 | 0100 1011 | 113 | 4B | K |
| 76 | 0100 1100 | 114 | 4C | L |
| 77 | 0100 1101 | 115 | 4D | M |
| 78 | 0100 1110 | 116 | 4E | N |
| 79 | 0100 1111 | 117 | 4F | O |
| 80 | 0101 0000 | 120 | 50 | P |
| 81 | 0101 0001 | 121 | 51 | Q |
| 82 | 0101 0010 | 122 | 52 | R |
| 83 | 0101 0011 | 123 | 53 | S |
| 84 | 0101 0100 | 124 | 54 | T |
| 85 | 0101 0101 | 125 | 55 | U |
| 86 | 0101 0110 | 126 | 56 | V |
| 87 | 0101 0111 | 127 | 57 | W |
| 88 | 0101 1000 | 130 | 58 | X |
| 89 | 0101 1001 | 131 | 59 | Y |
| 90 | 0101 1010 | 132 | 5A | Z |
| 91 | 0101 1011 | 133 | 5B | [ |
| 92 | 0101 1100 | 134 | 5C | \ |
| 93 | 0101 1101 | 135 | 5D | ] |
| 94 | 0101 1110 | 136 | 5E | ^ |
| 95 | 0101 1111 | 137 | 5F | _ |
| Dec | Bin | Oct | Hex | Char |
|---|---|---|---|---|
| 96 | 0110 0000 | 140 | 60 | ` |
| 97 | 0110 0001 | 141 | 61 | a |
| 98 | 0110 0010 | 142 | 62 | b |
| 99 | 0110 0011 | 143 | 63 | c |
| 100 | 0110 0100 | 144 | 64 | d |
| 101 | 0110 0101 | 145 | 65 | e |
| 102 | 0110 0110 | 146 | 66 | f |
| 103 | 0110 0111 | 147 | 67 | g |
| 104 | 0110 1000 | 150 | 68 | h |
| 105 | 0110 1001 | 151 | 69 | i |
| 106 | 0110 1010 | 152 | 6A | j |
| 107 | 0110 1011 | 153 | 6B | k |
| 108 | 0110 1100 | 154 | 6C | l |
| 109 | 0110 1101 | 155 | 6D | m |
| 110 | 0110 1110 | 156 | 6E | n |
| 111 | 0110 1111 | 157 | 6F | o |
| 112 | 0111 0000 | 160 | 70 | p |
| 113 | 0111 0001 | 161 | 71 | q |
| 114 | 0111 0010 | 162 | 72 | r |
| 115 | 0111 0011 | 163 | 73 | s |
| 116 | 0111 0100 | 164 | 74 | t |
| 117 | 0111 0101 | 165 | 75 | u |
| 118 | 0111 0110 | 166 | 76 | v |
| 119 | 0111 0111 | 167 | 77 | w |
| 120 | 0111 1000 | 170 | 78 | x |
| 121 | 0111 1001 | 171 | 79 | y |
| 122 | 0111 1010 | 172 | 7A | z |
| 123 | 0111 1011 | 173 | 7B | { |
| 124 | 0111 1100 | 174 | 7C | | |
| 125 | 0111 1101 | 175 | 7D | } |
| 126 | 0111 1110 | 176 | 7E | ~ |
Try It
If you would like to try printing something using ASCII encoding, you can try it out using Arduino. See this tutorial for getting started with Arduino.
Open the Arduino IDE and paste in the following code:
language:cvoid setup() { Serial.begin(9600);}void loop() { Serial.write(0x48); // H Serial.write(0x65); // e Serial.write(0x6C); // l Serial.write(0x6C); // l Serial.write(0x6F); // o Serial.write(0x21); // ! Serial.write(0x0A); // \n delay(1000);}Run it on your Arduino, and open a Serial console. You should see the "Hello!" appear over and over:
Notice that we had to use Serial.write() instead of Serial.print(). The write() command sends a raw byte across the serial line. print(), on the other hand, will try and interpret the number and send the ASCII-encoded version of that number. For example, Serial.print(0x48) would print 72 in the console.
Also, notice that we used the ASCII character 0x0A, which is the "line feed" control character. This causes the printer (or console in this case) to advance to the next line. It is similar to pressing the 'enter' key.
Resources and Going Further
There are many character encoding sets available. The most popular encoding for the World Wide Web is UTF-8. As of June 2016, UTF-8 is used in 87% of all web pages.
UTF-8 is backwards compatible with ASCII, which means the first 128 characters are the same as ASCII. UTF-8 can use 2, 3, and 4 bytes to encode characters from most modern written languages, including Latin, Greek, Cyrillic, Arabic, Chinese, Korean, and Japanese characters.
Knowledge of basic ASCII encoding can be useful when working in serial terminals. See the Serial Terminal Basics to learn how to use some of the many serial terminal programs available.
If you are interested in downloading the ASCII table in image format, click the button below. With an image, you can print it out and hang it on your wall, put it on a coffee mug, or have it printed on a mouse pad.
ASCII Table Images
As an enthusiast with a demonstrable depth of knowledge in the field, let's delve into the concepts covered in the provided article on character encoding, specifically ASCII (American Standard Code for Information Interchange). I'll provide insights into the historical context, the ASCII table, and related concepts.
Historical Background:
The article begins by highlighting the need for character encoding in computers, which operate in binary. It introduces the concept of assigning numbers to characters and mentions the creation of ASCII as one of the first character encoding standards.
Evidence of Expertise:
Understanding the historical development of ASCII is crucial. The American Standards Association (ASA), now ANSI, initiated ASCII in 1960, based on the 5-bit telegraph codes by Émile Baudot. ASCII, a 7-bit code, accommodated 128 characters, minimizing data transmission costs. President Lyndon B. Johnson's 1968 mandate further solidified ASCII's importance in US federal government computers.
ASCII Table:
The ASCII table is a key reference for understanding character encodings. It pairs each character with its assigned value between 0 and 127. The table is divided into control characters (first 32) and printable characters (95). Each character has a corresponding decimal, binary, octal, and hexadecimal representation.
Control Characters:
The first 32 characters in the ASCII table are control characters used for command instructions rather than printing. Examples include null (NUL), start of heading (SOH), line feed (LF), and carriage return (CR).
Printable Characters:
The remaining 95 characters are printable and include space, digits (0-9), uppercase and lowercase letters, and various symbols. Each character has its ASCII value, decimal, binary, octal, and hexadecimal representation.
Binary, Decimal, Hexadecimal Conversion:
The article suggests readers be familiar with binary and hexadecimal concepts. Binary represents numbers in base-2, and hexadecimal is often used to express binary numbers in groups of 4 bits.
Application with Arduino:
The article concludes with a practical application of ASCII encoding using Arduino. It provides a code snippet to print "Hello!" using ASCII values. It emphasizes the use of Serial.write() to send raw bytes and highlights the importance of understanding ASCII when working in serial terminals.
Further Exploration:
The article briefly mentions other encoding sets, with UTF-8 being highlighted as the most popular for the World Wide Web. It notes UTF-8's compatibility with ASCII and its ability to encode characters from various languages.
In summary, this article covers the historical context of ASCII, the ASCII table, binary and hexadecimal concepts, and practical applications with Arduino, showcasing a comprehensive understanding of character encoding principles.
