Kyeongho Lee

An all-analog multiphase delay-locked loop using a replica delay line for wide-range operation and low-jitter performance

This paper describes an all-analog multiphase delay-locked loop (DLL) architecture that achieves both wide-range operation and low-jitter performance. A replica delay line is attached to a conventional DLL to fully utilize the frequency range of the voltage-controlled delay line. The proposed DLL keeps the same benefits of conventional DLLs such as good jitter performance and multiphase clock generation. The DLL incorporates dynamic phase detectors and triply controlled delay cells with cell-level duty-cycle correction capability to generate equally spaced eight-phase clocks. The chip has been fabricated using a 0.35-/spl mu/m CMOS process. The peak-to peak jitter is less than 30 ps over the operating frequency range of 62.5-250 MHz, At 250 MHz, its jitter supply sensitivity is 0.11 ps/mV. It occupies smaller area (0.2 mm/sup 2/) and dissipates less power (42 mW) than other wide-range DLLs [2]-[7].

A CMOS serial link for fully duplexed data communication

This paper describes a CMOS serial link allowing fully duplexed 500 Mbaud serial data communication. The CMOS serial link is a robust and low-cost solution to high data rate requirements. A central charge pump PLL for generating multiphase clocks for oversampling is shared by several serial link channels. Fully duplexed serial data communication is realized in the bidirectional bridge by separating incoming data from the mixed signal on the cable end. The digital PLL accomplishes process-independent data recovery by using a low-ratio oversampling, a majority voting, and a parallel data recovery scheme. Mostly, digital approach could extend its bandwidth further with scaled CMOS technology. A single channel serial link and a charge pump PLL are integrated in a test chip using 1.2 /spl mu/m CMOS process technology. The test chip confirms upto 500 Mbaud unidirectional mode operation and 320 Mbaud fully duplexed mode operation with pseudo random data patterns. >

A 960-Mb/s/pin interface for skew-tolerant bus using low jitter PLL

This paper describes an I/O scheme for use in a high-speed bus which eliminates setup and hold time requirements between clock and data by using an oversampling method. The I/O circuit uses a low jitter phase-locked loop (PLL) which suppresses the effect of supply noise. Measured results show peak-to-peak jitter of 150 ps and r.m.s. jitter of 15.7 ps on the clock line. Two experimental chips with 4-pin interface have been fabricated with a 0.6 /spl mu/m CMOS technology, which exhibits the bandwidth of 960 Mb/s per pin.

A fully integrated CMOS frequency synthesizer with charge-averaging charge pump and dual-path loop filter for PCS- and cellular-CDMA wireless systems

This paper presents the design of a fully-integrated CMOS frequency synthesizer for PCS- and cellular-CDMA wireless systems. The proposed charge-averaging charge pump scheme suppresses fractional spurs and the VCO combined with coarse tuning improves phase noise characteristics. The improved architecture of the dual-path loop filter makes it possible to implement a large time constant on a chip. Fabricated in 0.35-/spl mu/m CMOS technology, this circuit provides 10 kHz channel spacing with phase noise of -106 dBc/Hz at 100 kHz offset. Power dissipation is 60 mW with 3.0 V supply.

Full-CMOS 2-GHz WCDMA direct conversion transmitter and receiver

This paper presents a full-CMOS transmitter and receiver for 2.0-GHz wide-band code division multiple access with direct conversion mixers and a DC-offset cancellation scheme. The direct conversion scheme combined with a multiphase sampling fractional-N prescaler alleviates the problems of the direct conversion transmitter and receiver. Digital gain control is merged into the baseband filters and variable-gain amplifiers to optimize the linearity of the system, reduce the noise, and improve the sensitivity. Variable-gain amplifiers with DC-offset cancellation loop eliminate the DC-offset in each stage. The chip implemented in 0.35-/spl mu/m CMOS technology shows the experimental results of 6 dBm maximum output power with 38-dB adjacent channel power rejection ratio at 1.92 MHz, 50-dB dynamic range, and 363-mW power consumption in the transmitter. The receiver shows -115.4 dBm sensitivity, a 4.0-dB noise figure, and a dynamic range of 80-dB with 396-mW power consumption.

A single-chip 2.4-GHz direct-conversion CMOS receiver for wireless local loop using multiphase reduced frequency conversion technique

A single-chip direct-conversion CMOS receiver for 2.4-GHz wide-band code-division multiple-access wireless local loop (WLL) is described. The chip includes a low noise amplifier, a 12-phase downconverter, a variable gain amplifier, a g/sub m/-C channel selection filter, a programmable phase-locked loop for seven channel frequencies, and a 4-bit flash analog-to-digital converter. The proposed multiphase reduced frequency conversion scheme combined with a multiphase sampling fractional-N prescaler, a cascaded dc-offset canceler and distributed automatic gain control loops offers solutions to problems of a direct-conversion receiver. Experimental results show -115-dBm sensitivity, 4.4-dB noise figure, and 95-dB dynamic range, which sufficiently meet commercial WLL specification.

An 800 Mbps multi-channel CMOS serial link with 3/spl times/ oversampling

A CMOS serial link is described that uses a digital PLL with 3/spl times/ over-sampling to recover both clock and data. An implementation with 0.6 /spl mu/m CMOS technology exhibits 800 Mbps operation with BER of less than 10E-12 for pseudo random number sequence. Chip area and power dissipation per channel at 800 Mbps are 2.1 mm/spl times/1.1 mm and 0.75 W, respectively.

A CMOS dual-band fractional-n synthesizer with reference doubler and compensated charge pump

A fully integrated dual-band frequency synthesizer in 0.35 /spl mu/m CMOS technology achieves a phase noise of -141 dBc/Hz at 1.25 MHz offset in the PCS band with a reference frequency doubler. Fractional spurs are reduced by 8.6 dB at 50 kHz offset with a replica compensated charge pump.

Comparison frequency doubling and charge pump matching techniques for dual-band /spl Delta//spl Sigma/ fractional-N frequency synthesizer

The frequency synthesizer with two LC-VCOs is fully integrated in a 0.35-/spl mu/m CMOS technology. In supporting dual bands, all building blocks except VCOs are shared. A current compensation scheme using a replica charge pump improves the linearity of the frequency synthesizer and, thus, suppresses spurious tones. To reduce the quantization noise from a /spl Delta//spl Sigma/ modulator and the noise from the building blocks except the VCO, the proposed architecture uses a frequency doubler with a noise-insensitive duty-cycle correction circuit (DCC) in the reference clock path. Power consumption is 37.8 mW with a 2.7-V supply. The proposed frequency synthesizer supports 10-kHz channel spacing with the measured phase noise of -114 dBc/Hz and -141 dBc/Hz at 100-kHz and 1.25-MHz offsets, respectively, in the PCS band. The fractional spurious tone at 10-kHz offset is under -54 dBc.

A 960 Mbps/pin interface for skew-tolerant bus using low jitter PLL

This paper describes an I/O scheme for use as a high-speed bus which eliminates setup and hold time requirements between clock and data by using oversampling method. The I/O circuit uses low jitter PLL which suppresses the effect of supply noise. Two experimental chips with 4 pin interface have been fabricated with 0.6 /spl mu/m CMOS technology, which exhibits the bandwidth of 960 Mbps per pin.