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• Low noise amplifier (LNA). Amplifies a faint signal from far away. LNA determines the sensitivity of a radio receiver.
• Power amplifier (PA). Amplifies a radio signal to high power for transmission.  PA determines the range of coverage for a transmitter.
• Local oscillator (LO). Provides the local carrier frequency for RF transmitter and receiver.
• Mixer. Mixes two signals. In a transmitter, the mixer is an ¡°up-converter,¡± which will mix a low-frequency analog signal with the LO signal to produce an RF signal. In a receiver, the mixer is a ¡°down-converter,¡± which will mix an RF signal with the LO signal to produce a low-frequency analog signal.
• Filter. Constrains the signal energy in a specific frequency band.  It plays the role of keeping different radio signals from interfering with each other.
• Switch. Controls the signal flow paths.
• Transceiver. Consists of a transmitter and receiver.

An RF circuit is a special type of analog circuit operating at the very high frequencies suitable for wireless transmission. One salient feature of an RF circuit is the use of inductive elements to tune the resonant circuit operation around a specific radio carrier frequency. The primary difference between RF design and low-frequency analog design is the type of analysis performed on the circuit.

In RF design, steady-state operation is of primary concern. The behavior of the circuit is often modeled in frequency domain with attention focused on the signal fidelity, noise, distortion, and interference. When modeling a modulated signal on an RF carrier, a hybrid time-frequency domain analysis is most efficient, where time domain focuses on the dynamic signal changes and frequency domain focuses on the RF carrier and its harmonics and intermodulation products. RF circuit variability, both manufacturing and design induced, must be modeled, and compensated for.

In analog design, circuit stimulus is treated as a continuously varying signal over time. In the context of wireless communications, analog design often refers to the ¡°low frequency¡± or ¡°baseband¡± circuit as opposed to the ¡°RF¡± circuit. In the context of wireline communications, analog design often refers to the analog front end or high-speed analog transceiver circuits. The behavior of the analog circuit is modeled in the time and frequency domains with attention focused on the fidelity/precision, consistency, and performance of the resultant waveforms. Circuit variability, both manufacturing and design induced, must be modeled, and compensated for as well.

The ²ÝÁñÉçÇø Custom Design Platform is a unified suite of design and verification tools featuring a complete RF development flow. It facilitates design/layout collaboration that makes it easy to communicate design intent and achieve RF design closure, as shown below.