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Chapter 2 : How are data represented ?

Chapter 2 : How are data represented ?. Why we care?. The accuracy of our results The speed of processing The range of alphabets available to us The size of the files we must store The quality of graphics on screen and on paper The time it takes for Internet download.

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Chapter 2 : How are data represented ?

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  1. Chapter 2: How are data represented?

  2. Why we care? • The accuracy of our results • The speed of processing • The range of alphabets available to us • The size of the files we must store • The quality of graphics on screen and on paper • The time it takes for Internet download

  3. Why computers work in binary? • Cheapest and simplest in design and engineering • Switch: on 1; off  0 • Circuit: voltages • 1.7 volts – higher  1 • 0.0 volts - 1.3 volts  0 • Voltages (1.3 to 1.7) are avoided in design • Mathematics: binary numbers • Using digits 0 and 1 only.

  4. Decimal vs. Binary • Decimal # system • 10 symbols: 1, 2, 3,…9, 0 • Base = 10 (We have 10 fingers) • Decimal number 2324 reads “2 thousands 3 hundreds twenty four”. • Binary # system • 2 symbols: 0 and 1 • Base = 2 • Binary number 1101 = ?

  5. Decimal vs. Binary Decimal # System: 2 3 2 4 . Each digit represents: 2*1000 3*100 2*10 4*1 Position values: 1000 100 10 1 Position values (base): 103 102 101 100 Value in Decimal: 2*1000+3*100+2*10+4*1 = 2324D Binary # System: 1 1 0 1 . Position values (base): 23 22 21 20 Position values: 8 4 2 1 Each digit represents: 1*8 1*4 0*2 1*1 Value in Decimal: 1*8+1*4+0*2+1*1 = 13D

  6. Why do computer work in binary? • Binary digits – bits • 8 bits = 1 byte • 210 bytes = 1024 bytes =1 kilobytes = 1KB • 220 bytes = 210 KB = 1 megabytes = 1MB • 230 bytes = 210 MB = 1 gigabytes = 1GB • 240 bytes = 210 GB = 1 terabytes = 1TB

  7. Types of data • Instructions • Computer instructions are coded in sequences of 0’s and 1’s • Numbers • 2324, -34.35, 34567890123.12345 • Characters and symbols • A, B, C, … Z, a, b, c,… z, • 0, 1, 2, 3 … 9, +, -, ), (, *, &, etc • Images • Photos, charts, drawings • Audio • Sound, music, etc • Video • Video clips and movies

  8. Representation of Numbers • Fixed-size-storage approach: • Computers allocate a specified amount of space for a number • Integers • 1 bit: 0 to 1 • 2 bits: 00, 01, 10, 11  0 to 3 • 4 bits: 0000, 0001, 0010, … 1111  0 to 15 • 1 byte: 0 to 255 • 2 bytes: -32768 to +32767 • 4 bytes: -2,147,483,648 to +2,147,483,647 Note: with 4 bytes for integers, any number smaller than -2,147,648 or larger than 2,147,483,647 would be incorrectly represented.,

  9. Representation of Numbers Binary representation of real numbers Binary # System: 1 0 . 1 1 1 Position values (base): 21 20 2-1 2-2 2-3 Position values: 2 1 1/2 1/4 1/8 Each digit represents: 1*2 0*1 1*0.5 1*0.25 1*0.125 Value in Decimal: 2 + ½ + ¼ +1/8 = 2.875D

  10. Representation of Numbers • Floating-point numbers for real numbers • Three parts of representation: • Sign (always 1 bits: 0 for + and 1 for -) • Significant digits (e.g., six bits) • the power of 2 for the leftmost digit (e.g., 3 bits) • Example for binary -1111.01 • Sign: 1 (negative) • Significant digits: 111101B • Power of 2: 011B • Example for binary +100.1101B • Sign: 0 (positive) • Significant digits: 100110B • Note: the last digit is lost, which is 1/16 in decimal • Power of 2: 010B

  11. Representation of Numbers • Single-precision floating-point numbers • Sign (always 1 bits: 0 for + and 1 for -) • Significant digits: 23 bits • exponent: 8 • Double-precision floating-point numbers • Sign (always 1 bits: 0 for + and 1 for -) • Significant digits: 52 bits • exponent: 11 • What you should know? • Computers can represent numbers only in limited accuracy. • E.g., when you enter a 20 digit decimal # into a program that uses single-precision, only about 7 digits are actually stored, the rest are lost. • Real examples: • Designing aircraft on p.35 • The Vancouver Stock Exchange Index on pp. 38-39

  12. Representation of Numbers // file: public_html/2005f-html/cil102/accuracy.c #include <stdio.h> int main() { int x, y, result; // x, y, and result all use 32 bits to represent integers (-2,147,648 to +2,147,483,647) char op; int i; for (i = 0; i < 100; i++) { printf("please enter an expression:\n"); scanf("%d %c %d", &x, &op, &y); if (op == '+') result = x + y; else if (op == '-') result = x - y; else { printf("Invalid operator!!"); break; } printf("%d %c %d = %d\n", x, op, y, result); } } // When you enter 2000000000 + 500000000, the result is -1794967296

  13. Representation of Numbers • Variable-size-storage approach: • Allow a wide-range of numbers to be stored accurately • Needs significant more time to process • Fixed-size approach is used more common than variable-size approach.

  14. Representation of characters • There are no visual letters A, B, C, etc stored in computers like we have in mind. • Letters and symbols are encoded in 8 bits – one byte - of 0’s and 1’s. • Keyboard converts keys A, B, C etc to their corresponding codes and • monitor converts the code into visual letters A, B, C etc on screen. • Two commonly used coding schemes: • ASCII: American Standard Code Information Interchange • EBCDIC: Extended Binary Coded Decimal Interchange Code

  15. Representation of characters

  16. Representation of characters • Foreign characters – two approaches • Use one byte per char • Ex., • ISO-8859-1 for Western (Roman) • ISO-8859-7 for Greek • ISO-2022-CN for simplified Chinese • Webpage: using “META charset=…” to specify which encoding is used. • Use two bytes per char/symbols • 16 bits have 65,536 combinations (characters) • Unicode coding system

  17. Representation of Images A picture is treated as a matrix of dots, called pixels.

  18. Representation of Images • The pixels are so small and close together we cannot really see them as separate dots. • Resolution: dots per inch (dpi) • 72 dpi for Web images • 600 or 1200 dpi for professional printers or home photo printers

  19. Representation of Images • The color of each pixel is represented using bits. • Black/White: one bit per pixel • 1-white and 0-black • Gray scale: one byte per pixel • 256 different degrees of gray (00000000 to 11111111) • 00000000 black, 01111111 intermediate gray, 11111111 white • Color: three bytes per pixel • Red, green, blue color • One byte for the intensity of each of the three color • 256 possible red, 256 green, 256 blue • Pure red: 11111111 for red byte, 00000000 for green and blue • White: 11111111 for all three bytes • Black: 00000000 for all three bytes

  20. Representation of Images • Image storage -- size • Gray scale: one byte per pixel E.g., A 3 X 5 picture with 300 dpi resolution 3 * 300 = 900 pixels per column 5 * 300 = 1500 pixels per row 900 * 1500 = 1,350,000 pixels/picture Needed storage = 1,350,000 bytes/picture = 1MB/picture • Color: three bytes per pixel E.g., A 3 X 5 picture with 300 dpi resolution 3 * 300 = 900 pixels per column 5 * 300 = 1500 pixels per row 900 * 1500 = 1,350,000 pixels/picture Needed storage = 3 (bytes per pixel) * 1,350,000 = 4,050,000 bytes/picture = 4MB/picture --- TOO BIG

  21. Representation of Images • Image compression • Color table • Most pictures contain a small # of different colors • Use a table to define colors that are actually used in the picture • Each pixel has an index to the color table. • Each image contains a color table and table indices • Example For a picture with 100 different colors, the color table would contain 100 entries, three bytes each entry for each color. One byte can be used as index to the table for each pixel.

  22. Representation of Images • Drawing commands • Draw picture using basic commands • Just as artists draws using a pencil or a brush and other basic movements • Example, • A house is drawn by sketching various elements (doors, windows, walls), adding color to them, and moving to the desired position.

  23. Representation of Images • Data averaging or sampling • Condense the size by selecting a smaller collection of information to store. • Many different ways of sampling and data averaging • An example: choose to store only every other pixel in an image (sampling)– reducing the size to half. To display the full picture, the computer need to fill in the missing data with, for example, the average of neighboring pixels (data averaging) • The resulting picture cannot be as sharp as the original • Lossy data compression

  24. What are “.gif”, “.ps”, “.jpg”, “.bmp” formats? • Commonly used image file formats -1 • Bitmap (.bmp) • Pixel-by-pixel storage of all color information for each pixel. • Lossless representation • Files are huge. • Graphics Interchange Format (.gif) • Use one or more color tables – the color table technique • Each table contains 256 colors. • Suitable for pictures with a small # (<256) of different colors (e.g., organization charts) • Not suitable for pictures with shading (e.g., photos)

  25. What are “.gif”, “.ps”, “.jpg”, “.bmp” formats? • Commonly used image file formats - 2 • PostScript (.ps) • Employ the drawing commands technique • “moveto” draws a line from current position to a new one and “arc” draws an arc given its center, radius, etc • General shapes can be used in multiple places • Fonts can be reused. • Useful when the picture can be rendered as a drawing or its contains many of the same elements (e.g., text of the same fonts) • Joint Photographic Experts Group (JPEG) (.jpg) • use the data averaging and sampling on 8*8 pixel blocks • User determines the level of details and clarity • High-quality image – 8*8 blocks maintain their contents • Low-quality image – info in 8*8 blocks is discarded  smaller files

  26. Comparison b/w jpg, gif, and ps • Pictures in the textbook http://www.cs.grinnell.edu/~walker/fluency-book/figures/chapter2/fig-2-overview.html • Comparison of .jpg and .gif http://www.siriusweb.com/tutorials/gifvsjpg/ • More on .jpg and .gif http://www.wfu.edu/~matthews/misc/jpg_vs_gif/JpgVsGif.html

  27. Summary of Image Representations • Other commonly used formats • Tiff: Tagged Image File Format • PNG: Portable Network Graphics • New formats will emerge • Understand the format and know the pros and cons • To learn: Google the format • Use programs (GIMP) to convert b/w formats

  28. Summary – chapter 2 • Computers work in binary • Integers may be constrained in size • Real numbers may have limited accuracy • Computations may produce roundoff errors, affecting accuracy • Characters and languages are encoded in binary • Pictures are displayed pixel by pixel • Color table, draw commands, and data averaging and sampling compression techniques • .bmp, jpg, .gif, .ps formats

  29. Binary vs. decimal Position value The base of a # system Bit/byte/KB/MB/GB/TB Integer binary #s Real # in binary Floating point numbers Representational error Roundoff errors ASCII/EBCDIC/Unicode Pixels Dots per inch (dpi) Bitmap Color table Data averaging Data sampling Data compression .jpg, .bmp, .gif, .ps Terminology

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