Wireless local-area networks (WLANs) are now well established in business enterprise networks, and growing in home applications. Until now, such networks have been based upon the IEEE 802.11b standard at 2.4 GHz. But increasing demands for more WLAN bandwidth and faster data rates have fostered the newer IEEE 802.11a and g standards with greater security and better support of multimedia services. To enable these emerging WLAN standards, RF Micro Devices (Greensboro, NC) has developed the model RFCS5420 software-driven, flexible dual-band, two-chip solution that works across all three standards and allows seamless connectivity among all three systems.

A chip set designed for connectivity to IEEE 802.11a/b/g networks will require three main building blocks:

1. A radio subsystem with transceivers capable of operating at 2.4 and 5 GHz.
2. A modem that supports orthogonal-frequency-division-multiplex (OFDM) and complementary-code-keying (CCK) modulation schemes.
3. A unified media-access controller (MAC) with support for IEEE 802.11a/b/g and the extensions to these standards.

The RFCS5420 chip set consists of a model RF5425 transceiver integrated circuit (IC) and a model RF5421 bandband/MAC IC. Both ICs are implemented in 0.18-µm, +1.8-VDC complementary-metal-oxide-semiconductor (CMOS) technology which offers extremely low power consumption in both transmit and receive modes. The RFCS5420 chip set can be functionally viewed as a composite of distinct IEEE 802.11a and IEEE 802.11b/g chip sets, each with its own radio, modem, and MAC subsystems that share a common host interface. The RF5425 transceiver is based on a True Zero-IF CMOS radio-transceiver architecture. Only front-end amplifiers and bandpass filters are needed for a complete dual-band 2.4- and 5-GHz WLAN radio solution.

The RF5421 baseband/MAC IC includes a complete implementation of IEEE 802.11a/b/g CCK and OFDM modems and an ARM9 processor that executes the bulk of the processing functions required for MAC processing. The RF5421 also includes hardware accelerators for modem aiding functions and full-speed encryption and security support. Together, the two ICs execute all of the Layer 1 and 2 functions required for IEEE 802.11a/b/g operation, thereby freeing significant high-speed processing chores from a host processor.

The RFCS5420 chip set (Fig. 1) supports data rates to 11 Mb/s (1, 2, 5.5, and 11 Mb/s) in CCK mode at 2.4 GHz and data rates to 54 Mb/s (6, 9, 12, 18, 24, 36, and 54 Mb/s) in OFDM mode at 2.4 and 5 GHz. The radio transceiver operates in the 2.4-GHz industrial-scientific-medical (ISM) band, the 4.9-to-5.1 GHz Japan band, and the 5.15-to-5.35-GHz UNII band. The chip set provides support for a wide range of modulation formats, including BPSK, QPSK, 16QAM, and 64 QAM. The chip set's unique AccuChannel equalization provides as much as 4-dB improvement in signal-to-noise ratio (SNR) in typical office environments, which translates into a 32-percent increase in WLAN range and about 70-percent more coverage area when operating in OFDM mode.

The RF5425's zero-IF radio IC features a direct-conversion architecture (Fig. 2), requiring only one mixer stage to convert the desired RF signals directly to and from baseband signals without any IF stages and without the need for external surface-acoustic-wave (SAW) filters. Most zero-IF radio designs also integrate the low-noise amplifier (LNA), voltage-controlled oscillator (VCO), and the baseband filters on a monolithic die. In fact, such integrated single-chip zero-IF transceivers have performed well for many years in cellular and pager applications and they are beginning to emerge in WLAN radio designs as well. A major advantage of the zero-IF architecture on CMOS is that it enables the implementation of a full dual-band transceiver on a monolithic die with a minimum increase in die size compared to a single-band implementation. The zero-IF radio architecture eliminates an IF stages, reducing complexity and power consumption. Furthermore, several on-chip circuits, i.e. synthesizers, can be shared for both bands.

Of course, no radio architecture is ideal. Some of the common RF problems inherent with the zero-IF architecture are DC offset, flicker noise, and LO pulling. DC offsets are mainly generated by the LO leakage, which self-mixes, thereby creating a DC component in the signal chain that affects the receiver performance and can cause the RF stages to saturate. Flicker noise, also known as 1/f noise, is low-frequency device noise that can corrupt signals in the receiver chain. Flicker noise is more pronounced with the zero-IF architecture because of the direct conversion to low-frequency baseband signals. Another concern with direct conversion is the pulling of the LO by the power-amplifier (PA) output, which affects the direct upconversion process. This is because the high-power PA output, which has a spectrum centered around the LO frequency, can disturb (or pull) the frequency of the transmitter VCO.

The RF5425 incorporates proprietary filters designed to provide superior adjacent-channel and alternate adjacent-channel rejection while minimizing noise contributions. An innovative VCO-design and frequency-planning architecture minimizes phase noise and LO pulling in the transmitter.

The other RF effects of zero-IF CMOS transceivers are mitigated by a combination of RF design techniques and baseband algorithms. A DC offset loop operates in conjunction with the baseband to dynamically correct for DC offset. Similarly, in-phase/quadrature (I/Q) mismatch is measured and corrected by the baseband at time of system initialization or channel changes. Close coupling of the RF5421 and RF5425 provide optimal performance for the zero-IF WLAN radio implementation.