Vedaslive - Youniverse

Home | Help

Prev<< See More Youniverse >>Next

Mar 2008


	By The Numbers
	As per industry surveys India will require an additional 3.1 million skilled manpower by 2010 for employment in industry, government and other sectors.


	Exams alert
	The BITSAT-2008 Online tests for admission to Integrated first degree programmes at various campuses of BITS Pilani for the academic year 2008-09 will be conducted during 9th May - 12th June 2008.


	Thus Spake
	Education is the most powerful weapon which you can use to change the world.
	- Nelson Mandela

	Interesting Facts

	Dubai : Dubai is the fastest growing city in the world. No taxes on income and there are no personal taxes either. In Dubai Emirates Mall you can ski indoors while shopping...... Dogs As Suicide Bombers : In the Second World War, during the Blitzkrieg campaign, German tanks were too fast and too powerful for Russian military...... History Of Amazon.com : Jeff Bezos coined the term Amazon.com from the earlier name Cadabra.com. It was the excellent way to present large volume online bookstore...... Google: Google, the Internet search company founded in September 1998 by Larry Page & Sergey Brin, got it's name from the word Googol...... Yahoo: Word "Yahoo" is shortcut for "Yet Another Hierarchical Officious Oracle". It was coined by PhD candidates at Stanford University: David Filo and Jerry Yang......

	More >>

	Radar

	Radar is a system that uses electromagnetic waves to identify the range, altitude, direction, or speed of both moving and fixed objects such as aircraft, ships, motor vehicles, weather formations, and terrain. A transmitter emits radio waves, which are reflected by the target and detected by a receiver, typically in the same location as the transmitter.Although the radio signal returned is usually very weak, radio signals can easily be amplified. This enables a radar to detect objects at ranges where other emissions, such as sound or visible light, would be too weak to detect.
	More >>

Smile Please..!

Parrot Talk

One day a guy walked into a pet store to buy a parrot.
He found one that he liked and went up to the counter to buy it. The store clerk saw which parrot he had picked out and said, ''That parrot repeats everything he hears.''
''That's alright,'' the man replied.
So the man bought the parrot and left the store.
As he was walking down the street, he saw a cop chasing a robber.
The cop hollered to his partner, ''Shoot him down, shoot him down!''
Then the parrot said, ''Shoot him down, shoot him down!''
They kept walking and found a man who was trying to pry his car off the ground with a crowbar because his wheels had been stolen.
The man said, ''Pop it up, pop it up!''
The parrot said, ''Pop it up, pop it up!''
They kept on walking to a carnival. A guy at a game stands yelled, ''Hit a big one, win a prize!''
The parrot said, ''Hit a big one, win a prize!''
Then they walked into a church and sat down.
The minister was in the middle of the sermon.
He said, ''The Lord is above us.''
The parrot said, ''Shoot him down, shoot him down!''
The minister said, ''The devil is below us.''
The parrot said, ''Pop it up, pop it up.''
Then the minister got angry and threw a bible at the parrot. The parrot ducked and the bible hit a fat lady behind him.
The parrot said, '' Hit a big one, win a prize!''

----------------------------------------------

Pilots & Stewards:-

An airplane was flying from LA to New York. About an hour into the flight, the pilot announced, "We have lost an engine, but don't worry, there are three left. However, instead of 5 hours it will take 7 hours to get to New York."
A little later, the pilot announced, "A second engine failed, but we still have two left. However, it will take 10 hours to get to New York."
Somewhat later, the pilot again came on the intercom and announced, "A third engine had died. Never fear, because the plane can fly on a single engine. However, it will now take 18 hours to get to new York."
At this point, one passenger said, "Gee, I hope we don't lose that last engine, or we'll be up here forever!"

From The Editors Desk

Heartiest Greetings!

In this issue of Youniverse, we have presented an Article on “Radars“, which provides an Introduction to the various principles, uses and future roadmap for Radars. The article traverses the historty of the Radars right from its inception, development in the second world war era and to its present form.

More >>

Complex Simplicities

AJAX

AJAX (Asynchronous JavaScript and XML), or Ajax, is a group of inter-related web development techniques used for creating interactive web applications. A primary characteristic is the increased responsiveness and interactivity of web pages achieved by exchanging small amounts of data with the server "behind the scenes" so that the entire web page does not have to be reloaded each time there is a need to fetch data from the server. This is intended to increase the web page's interactivity, speed, functionality, and usability.

More >>

RSS

RSS (Really Simple Syndication) is a family of Web feed formats used to publish frequently updated content such as blog entries, news headlines or podcasts. An RSS document, which is called a �feed,� �web feed,� or �channel,� contains either a summary of content from an associated web site or the full text.RSS makes it possible for people to keep up with their favorite web sites in an automated manner that�s easier than checking them manually.

More >>

CGI

The Common Gateway Interface (CGI) is a standard protocol for interfacing external application software with an information server, commonly a web server.

The task of such an information server is to respond to requests (in the case of web servers, requests from client web browsers) by returning output. Each time a request is received; the server analyzes what the request asks for, and returns the appropriate output.. The two simplest ways, for the server, of doing this are to identify the request whether it is for a file stored on disk, return the contents of that file; or it is for an executable command and possibly arguments, run the command and return its output.

More >>

top


Interesting Facts





		Dubai : Dubai is the fastest growing city in the world. No taxes on income and there are no personal taxes either. In Dubai Emirates Mall you can ski indoors while shopping, measuring 400 meters and using 6000 tons of snow. Burj Dubai will become the world's tallest building, along with the world's tallest man-made structure when it is completed. Eighty percent of Dubai residents are foreigners.

		Dogs As Suicide Bombers : In the Second World War, during the Blitzkrieg campaign, German tanks were too fast and too powerful for Russian military. Russian idea was to train the dogs to carry bombs under the German tanks. The trainers would first starve the dogs, and then train them to find a food under the tank. Unfortunately, problem was that dogs trained under the Soviet tanks not the loud German diesel tanks. Plan backfired on Soviets, but they did manage to disable a reported 300 German tanks.

		History Of Amazon.com : Jeff Bezos coined the term Amazon.com from the earlier name Cadabra.com. It was the excellent way to present large volume online bookstore. It is hard to believe but in the early Internet days, when Yahoo was dominant search engine, results on one page were listed alphabetically. Amazon would always appear above its competition for a specific keywords. This could be a breaking point for Jeff to expand and became what it is today.

		Google: Google, the Internet search company founded in September 1998 by Larry Page & Sergey Brin, got it's name from the word Googol, which represents number 1 followed with hundred zeros after it.

		Yahoo: Word "Yahoo" is shortcut for "Yet Another Hierarchical Officious Oracle". It was coined by PhD candidates at Stanford University: David Filo and Jerry Yang.

top

Radar

Radar is a system that uses electromagnetic waves to identify the range, altitude, direction, or speed of both moving and fixed objects such as aircraft, ships, motor vehicles, weather formations, and terrain. A transmitter emits radio waves, which are reflected by the target and detected by a receiver, typically in the same location as the transmitter. Although the radio signal returned is usually very weak, radio signals can easily be amplified. This enables a radar to detect objects at ranges where other emissions, such as sound or visible light, would be too weak to detect. Radar is used in many contexts, including meteorological detection of precipitation, air traffic control, police detection of speeding traffic, and by the military. It was originally called RDF (Radio Direction Finder) in Britain. The term RADAR was coined in 1941 as an acronym for Radio Detection and Ranging. The term has since entered the English language as a standard word, radar, losing the capitalization in the process.

History

Several inventors, scientists, and engineers contributed to the development of radar. The first to use radio waves to detect "the presence of distant metallic objects via radio waves" was Christian
H�lsmeyer, who in 1904 demonstrated the feasibility of detecting the presence of a ship in dense fog, but not its distance. He received Reichs Patent for his pre-radar device in April, and another patent on November 11 for a related amendment. He also received a patent in England for his telemobiloscope on September 22, 1904.

	Nikola Tesla, in August 1917, first established principles regarding frequency and power level for the first primitive radar units.

	Before the Second World War, developments by the Americans (Dr. Robert M. Page tested the first monopulse radar in 1934), the Germans, the French (French Patent in 1934), and the British (British Patent by Robert Watson-Watt in 1935), led to the first real radars. Hungarian Zoltán Bay produced a working model by 1936 at the Tungsram laboratory in the same vein.

	In 1934, Émile Girardeau, working with the first French radar systems, stated he was building radar systems "conceived according to the principles stated by Tesla".

	The war precipitated research to find better resolution, more portability and more features for the new defence technology. Post-war years have seen the use of radar in fields as diverse as air traffic control, weather monitoring, astrometry and road speed control.

Principles

A. Reflection

Electromagnetic waves reflect (scatter) from any large change in the dielectric or diamagnetic constants. This means that a solid object in air or a vacuum, or other significant change in atomic density between the object and what's surrounding it, will usually scatter radar (radio) waves. This is particularly true for electrically conductive materials, such as metal and carbon fibre, making radar particularly well suited to the detection of aircraft and ships. Radar absorbing material, containing resistive and sometimes magnetic substances, is used on military vehicles to reduce radar reflection. This is the radio equivalent of painting something a dark color.

Radar waves scatter in a variety of ways depending on the size (wavelength) of the radio wave and the shape of the target. If the wavelength is much shorter than the target's size, the wave will bounce off in a way similar to the way light is reflected by a mirror. If the wavelength is much longer than the size of the target, the target is polarized (positive and negative charges are separated), like a dipole antenna. This is described by Rayleigh scattering, an effect that creates the Earth's blue sky and red sunsets. When the two length scales are comparable, there may be resonances. Early radars used very long wavelengths that were larger than the targets and received a vague signal, whereas some modern systems use shorter wavelengths (a few centimetres or shorter) that can image objects as small as a loaf of bread.

Short radio waves reflect from curves and corners, in a way similar to glint from a rounded piece of glass. The most reflective targets for short wavelengths have 90° angles between the reflective surfaces.A structure consisting of three flat surfaces meeting at a single corner, like the corner on a box, will always
reflect waves entering its opening directly back at the source. These so-called corner reflectors are commonly used as radar reflectors to make otherwise difficult-to-detect objects easier to detect, and are often found on boats in order to improve their detection in a rescue situation and to reduce collisions. For similar reasons, objects attempting to avoid detection will angle their surfaces in a way to eliminate inside corners and avoid surfaces and edges perpendicular to likely detection directions, which leads to "odd" looking stealth aircraft. These precautions do not completely eliminate reflection because of diffraction, especially at longer wavelengths. Half wavelength long wires or strips of conducting material, such as chaff, are very reflective but do not direct the scattered energy back toward the source. The extent to which an object reflects or scatters radio waves is called its radar cross section.

B. Polarization

In the transmitted radar signal, the electric field is perpendicular to the direction of propagation, and this direction of the electric field is the polarization of the wave. Radars use horizontal, vertical, linear and circular polarization to detect different types of reflections. For example, circular polarization is used to minimize the interference caused by rain. Linear polarization returns usually indicate metal surfaces. Random polarization returns usually indicate a fractal surface, such as rocks or soil, and are used by navigation radars.

C. Interference

Radar systems must overcome several different sources of unwanted signals in order to focus only on the actual targets of interest. These unwanted signals may originate from internal and external sources, both passive and active. The ability of the radar system to overcome these unwanted signals defines its signal-to-noise ratio (SNR): the higher a system's SNR, the better it is in isolating actual targets from the surrounding noise signals.

D. Noise

Signal noise is an internal source of random variations in the signal, which is inherently generated to some degree by all electronic components. Noise typically appears as random variations superimposed on the desired echo signal received in the radar receiver. The lower the power of the desired signal, the more difficult it is to discern it from the noise (similar to trying to hear a whisper while standing near a busy road). Therefore, the most important noise sources appear in the receiver and much effort is made to minimize these factors. Noise figure is a measure of the noise produced by a receiver compared to an ideal receiver, and this needs to be minimized.

Noise is also generated by external sources, most importantly the natural thermal radiation of the background scene surrounding the target of interest. In modern radar systems, due to the high performance of their receivers, the internal noise is typically about equal to or lower than the external scene noise. An exception is if the radar is aimed upwards at clear sky, where the scene is so cold that it generates very little thermal noise.

E. Clutter

Clutter refers to actual radio frequency (RF) echoes returned from targets which are by definition uninteresting to the radar operators in general. Such targets mostly include natural objects such as ground, sea, precipitation (such as rain, snow or hail), sand storms, animals (especially birds), atmospheric turbulence, and other atmospheric effects (such as ionosphere reflections and meteor trails). Clutter may also be returned from man-made objects such as buildings and, intentionally, by radar countermeasures such as chaff.

Some clutter may also be caused by a long waveguide between the radar transceiver and the antenna. In a typical plan position indicator (PPI) radar with a rotating antenna, this will usually be seen as a "sun" or "sunburst" in the centre of the display as the receiver responds to echoes from dust particles and misguided RF in the waveguide. Adjusting the timing between when the transmitter sends a pulse and when the receiver stage is enabled will generally reduce the sunburst without affecting the accuracy of the range, since most sunburst is caused by diffused transmit pulse reflected before it leaves the antenna.

There are several methods of detecting and neutralizing clutter. Many of these methods rely on the fact that clutter tends to appear static between radar scans. Therefore, when comparing subsequent scans echoes, desirable targets will appear to move and all stationary echoes can be eliminated. Sea clutter can be reduced by using horizontal polarization, while rain is reduced with circular polarization (note that meteorological radars wish for the opposite effect, therefore using linear polarization the better to detect precipitation). Other methods attempt to increase the signal-to-clutter ratio.

Clutter may also originate from multipath echoes from valid targets due to ground reflection, atmospheric ducting or ionospheric reflection/refraction. This specific clutter type is especially bothersome, since it appears to move and behave like other normal (point) targets of interest, thereby creating a ghost. In a typical scenario, an aircraft echo is multipath-reflected from the ground below, appearing to the receiver as an identical target below the correct one. The radar may try to unify the targets, reporting the target at an incorrect height, or - worse - eliminating it on the basis of jitter or a physical impossibility. These problems can be overcome by incorporating a ground map of the radar's surroundings and eliminating all echoes which appear to originate below ground or above a certain height. In newer ATC (Air Traffic Control) radar equipment algorithms are used to identify the false targets by comparing the current pulse returns, to those adjacent, as well as calculating return improbabilities due to calculated height, distance, and radar timing.

F. Jamming

Radar jamming refers to RF signals originating from sources outside the radar, transmitting in the radar's frequency and thereby masking targets of interest. Jamming may be intentional, as with an anti-radar electronic warfare (EW) tactic, or unintentional, as with friendly forces operating equipment that transmits using the same frequency range. Jamming is considered an active interference source, since it is initiated by elements outside the radar and in general unrelated to the radar signals.

Jamming is problematic to radar since the jamming signal only needs to travel one-way (from the jammer to the radar receiver) whereas the radar echoes travel two-ways (radar-target-radar) and are therefore significantly reduced in power by the time they return to the radar receiver. Jammers therefore can be much less powerful than their jammed radars and still effectively mask targets along the line of sight from the jammer to the radar (Mainlobe Jamming). Jammers have an added effect of affecting radars along other line-of-sights, due to the radar receiver's sidelobes (Sidelobe Jamming).

Mainlobe jamming can generally only be reduced by narrowing the mainlobe solid angle, and can never fully be eliminated when directly facing a jammer which uses the same frequency and polarization as the radar. Sidelobe jamming can be overcome by reducing receiving sidelobes in the radar antenna design and by using an omnidirectional antenna to detect and disregard non-mainlobe signals. Other anti-jamming techniques are frequency hopping and polarization. See Electronic counter-counter-measures for details.

Radar signal processing

A. Distance measurement

One way to measure the distance to an object is to transmit a short pulse of radio signal (electromagnetic radiation), and measure the time it takes for the reflection to return. The distance is one-half the product of round trip time (because the signal has to travel to the target and then back to the receiver) and the speed of the signal. Since radio waves travel at the speed of light (186,000 miles per second or 300,000,000 meters per second), accurate distance measurement requires high-performance electronics.

In most cases, the receiver does not detect the return while the signal is being transmitted. Through the use of a device called a duplexer, the radar switches between transmitting and receiving at a predetermined rate. The minimum range is calculated by measuring the length of the pulse multiplied by the speed of light, divided by two. In order to detect closer targets one must use a shorter pulse length.

A similar effect imposes a maximum range as well. If the return from the target comes in when the next pulse is being sent out, once again the receiver cannot tell the difference. In order to maximize range, one wants to use longer times between pulses, or commonly referred to as a pulse repetition time (PRT).

These two effects tend to be at odds with each other, and it is not easy to combine both good short range and good long range in a single radar. This is because the short pulses needed for a good minimum range broadcast have less total energy, making the returns much smaller and the target harder to detect. This could be offset by using more pulses, but this would shorten the maximum range again. So each radar uses a particular type of signal. Long range radars tend to use long pulses with long delays between them, and short range radars use smaller pulses with less time between them. This pattern of pulses and pauses is known as the pulse repetition frequency (or PRF), and is one of the main ways to characterize a radar. As electronics have improved many radars now can change their PRF thereby changing their range. The newest radars actually fire 2 pulses during one cell. One for short range (~6 miles) and a separate signal for longer ranges (~60 miles).

The distance resolution and the characteristics of the received signal as compared to noise depends heavily on the shape of the pulse. The pulse is often modulated to achieve better performance thanks to a technique known as pulse compression.

B. Frequency modulation

Another form of distance measuring radar is based on frequency modulation. Frequency comparison between two signals is considerably more accurate, even with older electronics, than timing the signal. By changing the frequency of the returned signal and comparing that with the original, the difference can be easily measured.

This technique can be used in continuous wave radar, and is often found in aircraft radar altimeters. In these systems a "carrier" radar signal is frequency modulated in a predictable way, typically varying up and down with a sine wave or sawtooth pattern at audio frequencies. The signal is then sent out from one antenna and received on another, typically located on the bottom of the aircraft, and the signal can be continuously compared.

Since the signal frequency is changing, by the time the signal returns to the aircraft the broadcast has shifted to some other frequency. The amount of that shift is greater over longer times, so greater frequency differences mean a longer distance, the exact amount being the "ramp speed" selected by the electronics. The amount of shift is therefore directly related to the distance traveled, and can be displayed on an instrument. This signal processing is similar to that used in speed detecting Doppler radar. Example systems using this approach are AZUSA, MISTRAM, and UDOP.

C. Speed measurement

Speed is the change in distance to an object with respect to time. Thus the existing system for measuring distance, combined with a memory capacity to see where the target last was, is enough to measure speed. At one time the memory consisted of a user making grease-pencil marks on the radar screen, and then calculating the speed using a slide rule. Modern radar systems perform the equivalent operation faster and more accurately using computers.

However, if the transmitter's output is coherent (phase synchronized), there is another effect that can be used to make almost instant speed measurements (no memory is required), known as the Doppler effect. Most modern radar systems use this principle in the pulse-doppler radar system. Return signals from targets are shifted away from this base frequency via the Doppler effect enabling the calculation of the speed of the object relative to the radar. The Doppler effect is only able to determine the relative speed of the target along the line of sight from the radar to the target. Any component of target velocity perpendicular to this line of sight cannot be determined by Doppler alone tracking the target's azimuth over time must be used. Additional information of the nature of the Doppler returns may be found in the radar signal characteristics article.

It is also possible to make a radar without any pulsing, known as a continuous-wave radar (CW radar), by sending out a very pure signal of a known frequency. CW radar is ideal for determining the radial component of a target's velocity, but it cannot determine the target's range. CW radar is typically used by traffic enforcement to measure vehicle speed quickly and accurately where range is not important.

Radar components

A radar has different components:

	A transmitter that generates the radio signal with an oscillator such as a klystron or a magnetron and controls its duration by a modulator.

	A waveguide that links the transmitter and the antenna.

	A duplexer that serves as a switch between the antenna and the transmitter or the receiver for the signal when the antenna is used in both situations.

	A receiver. Knowing the shape of the desired received signal (a pulse), an optimal receiver can be designed using a matched filter.

	An electronic section that controls all those devices and the antenna to perform the radar scan ordered by a software.

	A link to end users.

Radar functions and roles

	Detection and search radars

	Threat radars

	Missile guidance systems

	Battlefield and reconnaissance radar

	Air Traffic Control and navigation

	Space and range instrumentation radar systems

	Weather-sensing Radar systems

	Radars for biological research

	Video games -Many video games dedicate a small portion of the screen to a subsidiary display that indicates the position of the player relative to other objects and players. The games sometimes refer to this sub-display as the 'radar', although it is not usually meant to represent a real radar system

Radar In The Atmospheric Observing And Predicting Systems

Weather forecasting and warning applications are relying increasingly on integrated observations from a variety of systems that are asynchronous in time and are non uniformly spaced geographically. Weather radar is a key instrument that provides rapid update and full volumetric coverage. On regional scales, the combination of the primary radar with subsidiary radars (either fixed or mobile) with satellite data, with automated meteorological measurements from aircraft, and with a network of ground-based meteorological instruments reporting in real time has been shown to provide enhanced nowcasting and short-term forecasting capabilities. Such capabilities improve severe local storm warnings (including forecasts of storm initiation, evolution, and decay), and they support activities such as construction, road travel, the needs of the aviation system (both civil and military), and recreation.

Future Uses of Radar Data

Weather radar data are being increasingly used not only in forecasting and warning applications but also in climatological studies as well as in a wide variety of other research areas. Weather radar provides observations on the small space and time scales that are essential for monitoring precipitation and diagnosing certain weather events as well as for supporting nowcasting systems, hydrologic models, and numerical weather prediction models. Issues of data quality are central to most such applications, particularly to efforts to automate the applications. Effective assimilation of radar data in the models also requires detailed error statistics.

Broad dissemination of weather radar data in real time facilitates the application of these data to diagnostic and forecasting operations. Archiving of radar base data, as well as product data, facilitates research activities, retrospective studies, and climatological investigations. A long-term objective of the radar and other weather observation systems is the establishment of an integrated observational system, whereby most or all of these observations (e.g., ground-based, airborne, and space-borne radar, along with satellite, surface, and other data) would be assimilated onto a four-dimensional grid to provide the most complete diagnosis of weather impacts possible. Numerical weather prediction models and nowcasting techniques would then provide forecasts from a few minutes to many hours. A broad array of products will be used to support decisions that improve safety to humans, improve operational efficiency, and make homeland defense efforts more effective.

top

AJAX

AJAX is asynchronous in that extra data is requested from the server and loaded in the background without interfering with the display and behavior of the existing page. JavaScript is the scripting language in which AJAX function calls are usually made. Data is retrieved using the �XML Http Request� object that is available to scripting languages run in modern browsers, or alternatively Remote Scripting in browsers that do not support XML Http Request. There is, however, no requirement that the asynchronous content be formatted in XML.

AJAX is a cross-platform technique usable on many different operating systems, computer architectures, and web browsers as it is based on open standards such as JavaScript and the DOM. There are free and open source implementations of suitable frameworks and libraries.

top

RSS

The Extensible Markup Language (XML) is a general-purpose markup language. It is classified as an extensible language because it allows its users to define their own tags. Its primary purpose is to facilitate the sharing of structured data across different information systems, particularly via the Internet.It is used both to encode documents and serialize data. In the latter context, it is comparable with other text-based serialization languages such as JSON and YAML. It started as a simplified subset of the Standard Generalized Markup Language (SGML), and is designed to be relatively human-legible. By adding semantic constraints, application languages can be implemented in XML. These include XHTML, RSS, Math ML, Graph ML, Scalable Vector Graphics, Music XML, and thousands of others. Moreover, XML is sometimes used as the specification language for such application languages. XML is recommended by the World Wide Web Consortium. It is a fee-free open standard.

RSS content can be read using software called an �RSS reader�, �feed reader� or an �aggregator�. The user subscribes to a feed by entering the feed�s link into the reader or by clicking an RSS icon in a browser that initiates the subscription process. The reader checks the user�s subscribed feeds regularly for new content, downloading any updates that it finds.

top

CGI

The Common Gateway Interface (CGI) is a standard protocol for interfacing external application software with an information server, commonly a web server.

The task of such an information server is to respond to requests (in the case of web servers, requests from client web browsers) by returning output. Each time a request is received; the server analyzes what the request asks for, and returns the appropriate output. The two simplest ways, for the server, of doing this are to identify the request whether it is for a file stored on disk, return the contents of that file; or it is for an executable command and possibly arguments, run the command and return its output.

CGI defines a standard way of doing the second. It defines how information about the server and the request is passed to the command in the form of arguments and environment variables, and how the command can pass back extra information about the output (such as the type) in the form of headers.

Example:- An example of a CGI program is the one implementing a wiki. The user agent requests the name of an entry; the server will retrieve the source of that entry's page (if one exists), transform it into HTML, and send the result back to the browser or prompt the user to create it. All wiki operations are managed by this one program.

Whenever a request to a matching URL is received, the corresponding program is called, with any data that the client sent as input. Output from the program is collected by the Web server, augmented with appropriate headers as defined by the CGI spec, and sent back to the client.

top

From The Editors Desk

Kayalvizhi M.S

Email - kayal@mindlogicx.com

Heartiest Greetings!

In this issue of Youniverse, we have presented an Article on �Radars�, which provides an Introduction to the various principles, uses and future roadmap for Radars. The article traverses the historty of the Radars right from its inception, development in the second world war era and to its present form.

Our regular section on Examinations informs you of the exams alert in the coming month. Section on Complex simplicities attempts to provide you an information on cutting edge technologies such as AJAX, RSS and CGI.

We hope that you would find the information presented in this issue of Youniverse interesting and useful.

We welcome your thought, views, comments & suggestions to share information as knowledge.

Editor

top

Feedback


	Please provide us with your feedback on how you feel about the Youniverse newsletter.You can also send us your queries on the VEDAS services.	top


	Email to info@vedaslive.com

Feedback Terms of use Sitemap Contact us