Spread Spectrum Modulation

Living in a world of Digital Communication,we would need to know how secure the comunication is and what are the ways handled to have it secure.This article describes about Spread Spectrum Technology,the art of secure digital communications which was once restricted only for Military communicaton and that is now being exploited for commercial and industrial purposes too.

Applications for commercial spread spectrum range from "wireless" LAN's (computer to computer local area networks), to integrated bar code scanner/palmtop computer/radio modem devices for warehousing, to digital dispatch, to digital cellular telephone communications, to "information society" city/area/state or country wide networks for passing faxes, computer data, email, or multimedia data.
What is Spread Spectrum?
The process of using a second modulating signal which is independent of the data and has the effect of increasing the bandwidth of the transmitted signal to well beyond the bandwidth of the data signal.
How Spread Spectrum Works?
Spread Spectrum uses wide band, noise-like signals. Because Spread Spectrum signals are noise-like, they are hard to detect. Spread Spectrum signals are also hard to Intercept or demodulate. Further, Spread Spectrum signals are harder to jam (interfere with) than narrowband signals. These Low Probability of Intercept (LPI) and anti-jam (AJ) features are why the military has used Spread Spectrum for so many years. Spread signals are intentionally made to be much wider band than the information they are carrying to make them more noise-like.

Spread Spectrum transmitters use similar transmit power levels to narrow band transmitters. Because Spread Spectrum signals are so wide, they transmit at a much lower spectral power density, measured in Watts per Hertz, than narrowband transmitters. This lower transmitted power density characteristic gives spread signals a big plus. Spread and narrow band signals can occupy the same band, with little or no interference. This capability is the main reason for all the interest in Spread Spectrum today.

Spread Spectrum Modulation is distinguished from wideband modulation schemes such as wideband Frequency Modulation (FM) by noting that in spread spectrum the waveform causing the spreading is independent of the data being transmitted. This permits the spreading waveform to be selected based on improving system performance in some way. PN sequences are selected as the spreading signals since they uniformly spread the signal power over the available bandwidth and provide other critical advantages such as permitting universal frequency reuse.


Three Types of Spread Spectrum Communications:

• Frequency hopping. The signal is rapidly switched between different frequencies within the hopping bandwidth pseudo-randomly, and the receiver knows before hand where to find the signal at any given time.

• Time hopping. The signal is transmitted in short bursts pseudo-randomly, and the receiver knows beforehand when to expect the burst.


• Direct sequence. The digital data is directly coded at a much higher frequency. The code is generated pseudo-randomly, the receiver knows how to generate the same code, and correlates the received signal with that code to extract the data.

Advantages:

• Resists intentional and non-intentional interference
• Has the ability to eliminate or alleviate the effect of multipath interference
• Can share the same frequency band (overlay) with other users
• Privacy due to the pseudo random code sequence (code division multiplexing)

Disadvantages:

• Complex circuitry
• Expensive to develop
• Very large bandwidths

To know more on the topic:

ABC of Spread Spectrum

Spreadspectrum Basics

CDMA and Spread Spectrum

Direct Sequence Spread Spectrum

Article on Spread Spectrum

Download material on Spread Spectrum

Spread spectrum System and its working

Article on Spread Spectrum

Bluetooth technology

The art of connecting things is becoming more and more complex every day. In this article, we will look at a method of connecting devices, called Bluetooth, that can streamline the process.

What is Bluetooth?
Bluetooth is an industrial specification for wireless personal area networks (PANs)or piconet. Bluetooth provides a way to connect and exchange information between devices such as mobile phones, laptops, Personal computer, printers, digital cameras, and video game consoles over a secure, globally unlicensed short-range radio frequency.

Bluetooth simplifies the discovery and setup of services between devices. Bluetooth devices advertise all of the services they provide. This makes using services easier because there is no longer a need to setup network addresses or permissions as in many other networks.

How Bluetooth Operates:
Bluetooth networking transmits data via low-power radio waves. It communicates on a frequency of 2.45 gigahertz (actually between 2.402 GHz and 2.480 GHz, to be exact). This frequency band has been set aside by international agreement for the use of industrial, scientific and medical devices (ISM).

One of the ways Bluetooth devices avoid interfering with other systems is by sending out very weak signals of about 1 milliwatt. By comparison, the most powerful cell phones can transmit a signal of 3 watts. The low power limits the range of a Bluetooth device to about 10 meters (32 feet), cutting the chances of interference between your computer system and your portable telephone or television. Even with the low power, Bluetooth doesn't require line of sight between communicating devices. The walls in your house won't stop a Bluetooth signal, making the standard useful for controlling several devices in different rooms.

Bluetooth can connect up to eight devices simultaneously. With all of those devices in the same 10-meter (32-foot) radius, you might think they'd interfere with one another, but it's unlikely. Bluetooth uses a technique called spread-spectrum frequency hopping that makes it rare for more than one device to be transmitting on the same frequency at the same time. In this technique, a device will use 79 individual, randomly chosen frequencies within a designated range, changing from one to another on a regular basis.

In the case of Bluetooth, the transmitters change frequencies 1,600 times every second, meaning that more devices can make full use of a limited slice of the radio spectrum. Since every Bluetooth transmitter uses spread-spectrum transmitting automatically, it’s unlikely that two transmitters will be on the same frequency at the same time. This same technique minimizes the risk that portable phones or baby monitors will disrupt Bluetooth devices, since any interference on a particular frequency will last only a tiny fraction of a second.

Advantages:
An economic wireless solution (both data & voice) for short distance.A global technology specification - an universal radio interface in 2.4 GHz ISM frequency band Stationary & mobile environments.No setup needed - always on in the background (Dynamic configurable).

Disadvantages:
The only real downsides are the data rate and security. Infrared can have data rates of up to 4 MBps, which provides very fast rates for data transfer, while Bluetooth only offers 1 MBps. The greater range and radio frequency (RF) of Bluetooth make it much more open to interception and attack. For this reason, security is a very key.

To know more on the topic:

• Bluetooth-Official Site
• A tutorial on Bluetooth
• Working of Bluetooth