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Integrated Circuit Image Gallery

Radio Frequency Integrated Circuit

Radio frequency (RF) chip sets have rapidly evolved to 5 GHz clock speeds, based on silicon-germanium (SiGE) bipolar complementary metal oxide semiconductor (BiCMOS) fabrication techniques and other advances by research laboratories such as Lucent Technologies and Raytheon. Playing a starring role in the defense industry's guidance systems, RF chips are more complicated to design than digital chips because they operate at higher frequencies. Despite many wireless communications and network systems termed "digital", the RF chips that support them are analog.

View a low magnification image of the radio frequency integrated circuit.

View a medium magnification image of the radio frequency integrated circuit.

Modeling, testing, and verifying RF circuits is more critical than for digital circuits since higher frequencies increase the level of interference, noise, and distortion. With radio transmission in wireless networks, RF chips allow access to more channels by dividing the limited bandwidth by frequency, time, and code. Multiplexed, these channels are then transmitted at higher throughput rates. Frequency division multiple access (FDMA) technology takes an analog radio transmission and splits the available frequency band into smaller fixed frequency channels. In 1983, commercial advanced mobile telephone service (AMPS) commenced as an analog mobile cellular system based on RF chips that use FDMA to divide the system bandwidth into 30-KHz channels for voice conversations. Each caller's conversation in the wireless network is transmitted at a single frequency range for the duration of the call. Newer, narrowband advanced mobile telephone service (N-AMPS) further divides the 30-KHz units into three 10-KHz channels.

Radio frequency chips that utilize time division multiple access (TDMA), convert analog signals into binary digital signals by chopping the analog signal into segments and encoding each segment. Each encoded segment is then assigned to a different time slot so that for example, a 4-KHz analog voice signal translates to a digital storage oscilloscope signal of 64,000 bits per second. By compressing and then multiplexing encoded signals, TMDA increases the conversation number in a single data stream. Some RF systems combine the time and frequency division multiple access (TDMA/FDMA technology) strategies into a single method for subdividing the available radio bandwidth based on frequency and time, or use code division multiple access (CDMA), based on the RF chipsets. Bluetooth wireless technology eliminates the need for cables within a local area network (LAN). Developed by computing and mobile communications leaders such as Nokia and Toshiba, Bluetooth provides powerful, low-cost connectivity that enables all types of audio-video, computing, and communications devices to "talk" without a physical connection.

Contributing Authors

Omar Alvarado, Thomas J. Fellers and Michael W. Davidson - National High Magnetic Field Laboratory, 1800 East Paul Dirac Dr., The Florida State University, Tallahassee, Florida, 32310.


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