Chapter 2 : Business Information

1. Chapter 2 : Business Information Business Data Communications, 5e

2. Analog Data • Continuous signal • Expressed as an oscillation (sine wave format) of frequency • Information rate and channel capacity are measured in hertz (Hz) of bandwidth (1 Hz = 1 cycle per second).

3. Basic Analog Terms • Wave frequency: Number of times a cycle occurs in given time period • Wave amplitude: Height of a wave cycle • Hertz (Hz): The number of times a wave cycle occurs in one second (commonly used measure of frequency)

4. Types of Information • Audio • Data • Image • Video

5. Understanding Audio • What makes sound? Vibration of air • How can we record that vibration? • How can we convert that to an electrical signal?

6. Digital Audio • For good representation, must sample amplitude at a rate of at least twice the maximum frequency • Measured in samples per second, or smp/sec • Telephone quality: 8000smp/sec, each sample using 8 bits • 8 bits * 8000smp/sec = 64kbps to transmit • CD audio quality: 44000smp/sec, each sample using 16 bits • 16 bits * 44000smp/sec = 1.41mbps to transmit clearly

7. Networking Implications for Voice Communication • Requires powerful, flexible intralocation facility, and access to outside services (e.g. telcos) • In-house alternatives • PBX (perform switching in the customer side) • Centrex (perform switching in the telcos)

8. Digital Data • Represented as a sequence of discrete symbols from a finite “alphabet” of text and/or digits • Rate and capacity of a digital channel measured in bits per second (bps) • Digital data is binary: uses 1s and 0s to represent everything • Data encoded in strings • ASCII, IRA, UTF, etc • Data is often redundant (why?)

9. Data Networking Implications • Vary significantly based on application and data types • Example: Transferring financial transactions data from CitiBank-Taipei to CitiBank-NY (Not just real-time, but also . . . ) • Daily reports vs monthly reports • DHL parcel tracking • Response time often a key component • What sort of technologies are needed to support such applications?

10. Understanding Images • Vector graphics • Collection of straight and curved line segments • Image described as a collection of segments • Raster graphics • Two-dimensional array of “spots” (pixels) • Also called “bitmap” image • In terms of memory, which kind of graphic needs more memory?

11. Image and Document Formats • Common Raster Formats • JPEG • GIF • Common Document Formats • PDF • Postscript • Both include text and graphics

12. Networking Implications for Image Data • More pixels=better quality=larger size • More compression=reduced quality=increased speed • “Lossy” gives from 10:1 to 20:1 compression • “Lossless” gives less than 5:1 • Format (vector vs bitmapped/raster) affects size and therefore bandwidth requirements • Choices in imaging technology, conversion, and communication all affect end-user’s satisfaction

13. Video Communication • Sequences of images over time • Same concept as image, but with the dimension of time added • Significantly higher bandwidth requirements in order to send images (frames) quickly enough • Similarity of adjacent frames allows for high compression rates

14. Performance Measure:Response Time • User response time • System response time • Network transfer time (throughput)

15. Bandwidth Requirements • Review Figure 2.7 • What happens when bandwidth is insufficient? • How long does it take to become impatient? • Let us feel about that . . . • YouTube • Is data communication ever “fast enough”?