Jvckenwood Is Pleased to Introduce Their Nexedgeã‚â® Family of Digital Portable Radios.
Radio
Background
The radio receives electromagnetic waves from the air that are sent by a radio transmitter. Electromagnetic waves are a combination of electric and magnetic fields that overlap. The radio converts these electromagnetic waves, chosen a point, into sounds that humans tin hear.
Radios are a function of everyday life. Not only are they used to play music or as alarms in the morning, they are besides used in cordless phones, cell phones, baby monitors, garage door openers, toys, satellites, and radar. Radios also play an important role in communications for police, fire, manufacture, and the military. Although in that location are many types of radios—clock, car, apprentice (ham), stereo—all contain the aforementioned basic components.
Radios come in all shapes and sizes, from a little AM/FM "Walkman" to a highly sophisticated, multi-mode transceiver where both the transmitter and receiver are combined in ane unit. The nigh common modes for a broadcast radio are AM (amplitude modulation) and FM (frequency modulation). Other modes used by ham radio operators, industry, and the war machine are CW (continuous wave using Morse code), SSB (single sideband), digital modes such equally telemetry, radio teletype, and PSK (phase shift keying).
History
Guglielmo Marconi successfully sent the showtime radio message across the Atlantic Ocean in December 1901 from England to Newfoundland. Marconi's radio did not receive vocalism or music. Rather, information technology received buzzing sounds created by a spark gap transmitter sending a signal using Morse lawmaking.
The radio got its voice on Christmas Eve 1906. Every bit dozens of ship and apprentice radio operators listened for the evening's traffic messages, they were amazed to hear a man'due south phonation calling "CQ, CQ" (which ways calling all stations, I have letters) instead of the customary dits and dahs of Morse code. The bulletin was transmitted by Professor Reginald Aubrey Fessenden from a small radio station in Brant Rock, Massachusetts.
In the years from 1904 to 1914, the radio went through many refinements with the invention of the diode and triode vacuum tubes. These devices enabled better transmission and reception of voice and music. Too during this fourth dimension menstruation, the radio became standard equipment on ships crossing the oceans.
The radio came of age during World War I. Military leaders recognized its value for communicating with the infantry and ships at sea. During the WWI, many advancements were made to the radio making it more powerful and compact. In 1923, Edwin Armstrong invented the superhetrodyne radio. Information technology was a major advancement in how a radio worked. The basic principles used in the superhetrodyne radio are nonetheless in use today.
On November ii, 1920 the first commercial radio station went on the air in Pittsburgh, Pennsylvania. It was an instant success, and began the radio revolution called the "Golden Age of Radio." The Gilded Age of Radio lasted from the early 1920s through the late 1940s when television brought in a whole new era. During this Gilded Age, the radio evolved from a uncomplicated device in a bulky box to a complex piece of equipment housed in beautiful wooden cabinets. People would assemble effectually the radio and listen to the latest news and radio plays. The radio occupied a similar position as today'southward television set.
On June xxx, 1948 the transistor was successfully demonstrated at Bell Laboratories. The transistor allowed radios to become compact, with the smallest ones able to fit in a shirt pocket. In 1959, Jack Kilby and Robert Noyce received the first patent for the integrated excursion. The infinite program of the 1960s would bring more advances to the integrated excursion. At present, a radio could fit in the frame of eyeglasses or inside a pair of pocket-sized stereo earphones. Today, the frequency dial printed on the cabinet has been replaced with light emitting diodes or liquid crystal displays.
Raw Materials
Today's radio consists of an antenna, printed circuit board, resistors, capacitors, coils and transformers, transistors, integrated circuits, and a speaker. All of these parts are housed in a plastic case.
An internal antenna consists of pocket-size-diameter insulated copper wire wound around a ferrite core. An external antenna consists of several aluminum tubes that slide within 1 another.
The printed excursion board consists of a copper-clad pattern cemented to a phenolic board. The copper pattern is the wiring from component to component. It replaces most of the wiring used in before radios.
Resistors limit the flow of electricity. They consist of a carbon picture show deposited on a cylindrical substrate, encased in a plastic (alkyd polyester) housing, with wire leads made of copper.
Capacitors store an electric accuse and let alternating current to flow through an electrical circuit but prevent straight current from flowing in the aforementioned excursion. Fixed capacitors consist of two extended aluminum foil electrodes insulated by polypropylene moving-picture show, housed in a plastic or ceramic housing with copper wire leads. Variable capacitors have a gear up of fixed aluminum plates and a set up of rotating aluminum plates with an air insulator.
Coils and transformers perform similar functions. Their purpose is to insulate a circuit while transferring free energy from one circuit to some other. They consist of ii or more sets of copper wire coils either wound on an insulator or mounted side-by-side with air as the insulator.
Transistors consist of germanium or silicon encased in a metallic housing with copper wire leads. The transistor controls the catamenia of electricity in a circuit. Transistors replaced vacuum tubes used in earlier radios.
The integrated circuit houses thousands of resistors, capacitors, and transistors into a modest and compact package called a chip. This chip is about the size of the nail on the pinkie. The bit is mounted in a plastic case with aluminum tabs that allow information technology to be mounted to a printed excursion board.
Design
Radios consist of many specialized electronic circuits designed to perform specific tasks—radio frequency amplifier, mixer, variable frequency oscillator, intermediate frequency amplifier, detector, and audio amplifier.
The radio frequency amplifier is designed to amplify the signal from a radio broadcast transmitter. The mixer takes the radio signal and combines it with another betoken produced by the radio'south variable frequency oscillator to produce an intermediate frequency. The variable frequency oscillator is the tuning knob on the radio. The produced intermediate frequency is amplified past the intermediate frequency amplifier. This intermediate bespeak is sent to the detector which converts the radio signal to an sound signal. The audio amplifier amplifies the sound signal and sends it to the speaker or earphones.
The simplest AM/FM radio will have all of these circuits mounted on a single circuit lath. Most of these circuits can be contained in a single integrated circuit. The volume control (a variable resistor), tuning knob (a variable capacitor), speaker, antenna, and batteries can be mounted either on the printed circuit board or in the radio'southward case.
The Manufacturing
Process
In that location is no single process for manufacturing a radio. The manufacturing process depends upon the design and complexity of the radio.
The simplest radio has a single excursion board housed in a plastic example. The most circuitous radio has many circuit boards or modules housed in aluminum instance.
Manufacturers buy the basic components such as resistors, capacitors, transistors, integrated circuits, etc., from vendors and suppliers. The printed circuit boards, ordinarily proprietary, may be manufactured in house. Many times, manufacturers volition purchase consummate radio modules from an vendor. Most of the manufacturing operations are performed by robots. These include the printed circuit boards and mounting of the components on the printed circuit board. Mounting of the printed circuit board and controls into the instance and some soldering operations are usually washed by hand.
- The blank printed circuit lath consists of a drinking glass epoxy resin with a thin copper film cemented to ane or both sides. A lite sensitive photoresist film is placed over the copper moving-picture show. A mask containing the electrical circuitry is placed over the photoresist film. The photoresist motion-picture show is exposed to ultraviolet light. The photoresist image is developed, transferring the image to the copper film. The unexposed areas dissolve during etching and produce a printed excursion on the board.
- Holes are drilled in designated locations on the printed excursion lath to have the components. And so, the board is pre-soldered past dipping it in a bathroom of hot solder.
- Smaller electronic components such every bit resistors, capacitors, transistors, integrated circuits, and coils are installed in their designated holes on the printed excursion board and soldered to the board. These operations can exist performed by hand or past robots.
- Larger components such equally power transformer, speaker, and antenna are mounted either on the PCB or cabinet with screws or metal spring tabs.
- The case that houses the radio can be made either of plastic or aluminum. Plastic cases are made from pellets that are melted and injected into a mold. Aluminum cases are stamped into shape from sheet aluminum by a metal press.
- External components not mounted on the printed circuit board tin be the antenna, speaker, power transformer, volume, and frequency controls are mounted in the case with either screws, rivets, or plastic snaps. The printed circuit lath is then mounted in the case with screws or snaps. The external components are connected and soldered to the printed circuit board with insulated wires made of copper and plastic insulation.
Quality Control
Since nigh of the components or a radio are manufactured by specialized vendors, the radio manufacturer must rely on those venders to produce quality parts. However, the radio manufacturer volition accept random samples of each component received and inspect/test them to ensure they come across the required specifications.
Random samples of the final radio assembly are too inspected to ensure quality. The overall unit is inspected for flaws—both physical and electrical. The radio is played to ensure it can select radio frequencies it's blueprint to receive, and that the sound output is within specifications.
Byproducts/Waste material
Today's environmental awareness dictates that all waste be disposed of properly. Most byproducts from the construction of a radio can be reclaimed. The carving solutions used in the printed excursion board manufacture are sent to chemic reclamation centers. Scraps from the leads of electronic components are sent to metal waste recovery centers where they are melted to create new products.
The Futurity
Radios are being combined with computers to connect the calculator to the Internet via satellites. Eventually radios will convert from analog to digital broadcasting. Analog signals are subject to fade and interference, digital signals are not. They can produce high quality sound like that found on a CD.
Digital radios can be programmed for specific stations, types of music, news, etc. Eventually, radios will accept mini-computers congenital in to process sounds in numerical patterns "digits" rather than an analog waveform. This will permit listeners to program their radios for favorite radio stations, music type, stock quotes, traffic information, and much more.
Ernst S. Sibberson
Source: http://www.madehow.com/Volume-7/Radio.html
0 Response to "Jvckenwood Is Pleased to Introduce Their Nexedgeã‚â® Family of Digital Portable Radios."
Post a Comment