A 1.76-GHz 22.6-mW /spl Delta//spl Sigma/ fractional-n frequency synthesizer

A /spl Delta//spl Sigma/ fractional-N frequency synthesizer for the 2-GHz-range wireless communication applications is implemented in a 0.35-/spl mu/m BiCMOS process, using only CMOS components. The synthesizer achieves a close-in phase noise of -81 dBc/Hz, while the spurious tones are at -85 dBc. The synthesizer features a multiple-modulus prescaler employing the phase-switching architecture to minimize the power dissipation. The entire prescaler, including the gigahertz-speed first stages, is implemented using full-swing logic. The current source structure employed in the charge pump provides a constant output current over a wide, almost rail-to-rail output voltage range. The power dissipation of the synthesizer chip is 22.6 mW from a 2.7-V supply.     

A direct digital frequency synthesizer with fourth-order phase domain /spl Delta//spl Sigma/ noise shaper and 12-bit current-steering DAC

This paper presents a direct digital frequency synthesizer (DDFS) with a 16-bit accumulator, a fourth-order phase domain single-stage /spl Delta//spl Sigma/ interpolator, and a 300-MS/s 12-bit current-steering DAC based on the Q/sup 2/ Random Walk switching scheme. The /spl Delta//spl Sigma/ interpolator is used to reduce the phase truncation error and the ROM size. The implemented fourth-order single-stage /spl Delta//spl Sigma/ noise shaper reduces the effective phase bits by four and reduces the ROM size by 16 times. The DDFS prototype is fabricated in a 0.35-/spl mu/m CMOS technology with active area of 1.11mm/sup 2/ including a 12-bit DAC. The measured DDFS spurious-free dynamic range (SFDR) is greater than 78 dB using a reduced ROM with 8-bit phase, 12-bit amplitude resolution and a size of 0.09 mm/sup 2/. The total power consumption of the DDFS is 200mW with a 3.3-V power supply.     

A multiband /spl Delta//spl Sigma/ fractional-N frequency synthesizer for a MIMO WLAN transceiver RFIC

This work presents a shared fractional-N synthesizer used by two dual-band 802.11 radios integrated on a single chip for 2/spl times/2 multiple-input multiple-output (MIMO) applications. Additional 2/spl times/2 MIMO chips can be used in a system by phase synchronizing the signal paths through a bidirectional LO porting scheme developed for this application. This synthesizer was fully integrated with the exception of an off-chip loop filter. The synthesizer is a /spl Delta//spl Sigma/-based fractional-N frequency synthesizer with three on-chip LC tuned VCOs to cover the entire frequency bands specified in the IEEE 802.11a/b/g and Japanese WLAN standards. The radio uses a variable IF frequency so that both the RF LO and IF LO can be derived from a single synthesizer saving chip area and power. The synthesizer includes a programmable second/third-order /spl Delta//spl Sigma/ noise shaper, a phase frequency detector, a differential charge pump, and a 6-bit multimodulus divider (MMD). The nominal jitter from 100 Hz to 10 MHz is 0.63-0.86/spl deg/ rms in the 5-GHz band and 0.35-0.43/spl deg/ rms in the 2.4-GHz band. The maximum frequency deviation of the synthesizer when enabling the transmitter is less than 150 kHz and the frequency error settles to 2 kHz in less than 12 /spl mu/s. For MIMO applications requiring more than two full paths, a single synthesizer on one die can be used to generate the LOs for all other radios integrated in different dies.     

A 700-kHz bandwidth /spl Sigma//spl Delta/ fractional synthesizer with spurs compensation and linearization techniques for WCDMA applications

A /spl Sigma//spl Delta/ fractional-N frequency synthesizer targeting WCDMA receiver specifications is presented. Through spurs compensation and linearization techniques, the PLL bandwidth is significantly extended with only a slight increase in the integrated phase noise. In a 0.18-/spl mu/m standard digital CMOS technology a fully integrated prototype with 2.1-GHz output frequency and 35 Hz resolution has an area of 3.4 mm/sup 2/ PADs included, and it consumes 28 mW. With a 3-dB closed-loop bandwidth of 700 kHz, the settling time is only 7 /spl mu/s. The integrated phase noise plus spurs is -45 dBc for the first WCDMA channel (1 kHz to 1.94 MHz) and -65 dBc for the second channel (2.5 to 6.34 MHz) with a worst case in-band (unfiltered) fractional spur of -60 dBc. Given the extremely large bandwidth, the synthesizer could be used also for TX direct modulation over a broad band. The choice of such a large bandwidth, however, still limits the spur performance. A slightly smaller bandwidth would fulfill WCDMA requirements. This has been shown in a second prototype, using the same architecture but employing an external loop filter and VCO for greater flexibility and ease of testing.     

A 1.5-V direct digital synthesizer with tunable delta-sigma modulator in 0.13-/spl mu/m CMOS

In direct digital synthesizer (DDS) applications, the drawback of the conventional delta sigma (/spl Delta//spl Sigma/) modulator structure is that its signal band is fixed. In the new architecture presented in this paper, the signal band of the /spl Delta//spl Sigma/ modulator is tuned according to the DDS output frequency. We use a hardware-efficient phase-to-sine amplitude converter in the DDS that approximates the first quadrant of the sine function with 16 equal-length piecewise second-degree polynomial segments. The DDS is capable of frequency, phase, and quadrature amplitude modulation. The die area of the chip is 2.02 mm/sup 2/ (0.13 /spl mu/m CMOS technology). The total power consumption is 138 mW at 1.5 V with an output frequency of 63.33 MHz at a clock frequency of 200 MHz (D/A converter full-scale output current: 11.5 mA).     

A continuous-time sigma-delta modulator with 88-dB dynamic range and 1.1-MHz signal bandwidth

This paper presents the design and experimental results of a continuous-time /spl Sigma//spl Delta/ modulator for ADSL applications. Multibit nonreturn-to-zero (NRZ) DAC pulse shaping is used to reduce clock jitter sensitivity. The nonzero excess loop delay problem in conventional continuous-time /spl Sigma//spl Delta/ modulators is solved by our proposed architecture. A prototype third-order continuous-time /spl Sigma//spl Delta/ modulator with 5-bit internal quantization was realized in a 0.5-/spl mu/m double-poly triple-metal CMOS technology, with a chip area of 2.4 /spl times/ 2.4 mm/sup 2/. Experimental results show that the modulator achieves 88-dB dynamic range, 84-dB SNR, and 83-dB SNDR over a 1.1-MHz signal bandwidth with an oversampling ratio of 16, while dissipating 62 mW from a 3.3-V supply.     

A wide-band 280-MHz four-path time-interleaved bandpass sigma-delta modulator

This paper describes a 0.35-/spl mu/m CMOS fourth-order bandpass analog-digital sigma-delta (/spl Sigma//spl Delta/) modulator for wide-band base stations receivers. The modulator, based on a time-interleaved four-path architecture, achieves an equivalent sampling frequency of 280 MHz, although the building blocks operate at only 70 MHz. In measurements, the prototype chip achieves a dynamic range of 72 dB (12 bits of resolution) with a signal bandwidth of 4.375 MHz centered around an intermediate frequency of 70 MHz. The measured spurious-free dynamic range is 69 dB. The /spl Sigma//spl Delta/ modulator dissipates 480 mW from a 3.3-V supply, including voltage reference buffers and output pads with high-driving capabilities, and occupies 20 mm/sup 2/ of silicon area.     

A 3.3-mW /spl Sigma//spl Delta/ modulator for UMTS in 0.18-/spl mu/m CMOS with 70-dB dynamic range in 2-MHz bandwidth

A quadrature fourth-order, continuous-time, /spl Sigma//spl Delta/ modulator with 1.5-b quantizer and feedback digital-to-analog converter (DAC) for a universal mobile telecommunication system (UMTS) receiver chain is presented. It achieves a dynamic range of 70 dB in a 2-MHz bandwidth and the total harmonic distortion is -74 dB at full-scale input. When used in an integrated receiver for UMTS, the dynamic range of the modulator substantially reduces the need for analog automatic gain control and its tolerance of large out-of-band interference also permits the use of only first-order prefiltering. An IC including an I and Q /spl Sigma//spl Delta/ modulator, phase-locked loop, oscillator, and bandgap dissipates 11.5 mW at 1.8 V. The active area is 0.41 mm/sup 2/ in a 0.18-/spl mu/m 1-poly 5-metal CMOS technology.     

A 1-V 10.7-MHz switched-opamp bandpass /spl Sigma//spl Delta/ modulator using double-sampling finite-gain-compensation technique

A 1 V switched-capacitor (SC) bandpass sigma-delta (/spl Sigma//spl Delta/) modulator is realized using a high-speed switched-opamp (SO) technique with a sampling frequency of up to 50 MHz, which is improved ten times more than prior 1 V SO designs and comparable to the performance of the state-of-the-art SC circuits that operate at much higher supply voltages. On the system level, a fast-settling double-sampling SC biquadratic filter architecture is proposed to achieve high-speed operation. A low-voltage double-sampling finite-gain-compensation technique is employed to realize a high-resolution /spl Sigma//spl Delta/ modulator using only low-DC-gain opamps to maximize the speed and to reduce power dissipation. On the circuit level, a fast-switching methodology is proposed for the design of the switchable opamps to achieve a switching frequency up to 50 MHz. Implemented in a 0.35-/spl mu/m CMOS process (V/sub TP/=0.82 V and V/sub TN/=0.65 V) and at 1 V supply, the modulator achieves a measured peak signal-to-noise-and-distortion ratio (SNDR) of 42.3 dB at 10.7 MHz with a signal bandwidth of 200 kHz, while dissipating 12 mW and occupying a chip area of 1.3 mm/sup 2/.     

A 2-GHz analog-to-digital delta-sigma modulator for CDMA receivers with 79-dB signal-to-noise ratio in 1.23-MHz bandwidth

This paper presents the design of a second-order single-bit analog-to-digital continuous-time delta-sigma modulator (CT-/spl Delta//spl Sigma/M) that can be used in wireless CDMA receivers. The CT-/spl Delta//spl Sigma/M samples at 2 GHz, consumes 18 mW at 1.8 V and has a 79-dB signal-to-noise ratio (SNR) over a 1.23-MHz bandwidth. The CT-/spl Delta//spl Sigma/M was fabricated in a 0.18-/spl mu/m 1-poly 6-metal, CMOS technology and has an active area of approximately 0.892 mm/sup 2/. The /spl Delta//spl Sigma/M's critical performance specifications are derived from the CDMA receiver specifications.     

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 fully integrated two-channel A/D interface for the acquisition of cardiac signals in implantable pacemakers

This work presents an input stage for a cardiac pacemaker fully integrated in 0.35-/spl mu/m CMOS technology. The system can acquire and digitize to 8 bits both atrial and ventricular electrical activity. Log-domain circuits are exploited to amplify and filter the input signal, while /spl Sigma//spl Delta/ modulation is exploited to convert it. The design is power optimized, indeed the current consumption is limited to 2.9 /spl mu/A, while the power supply ranges from 2.8 to 1.8 V. The total area is 2.2 mm/sup 2/ and experimental data prove correct filtering and a total dynamic range of at least 47 dB.     

A continuous-time /spl Sigma//spl Delta/ ADC with increased immunity to interferers

Receivers are being digitized in a quest for flexibility. Analog filters and programmable gain stages are being exchanged for digital processing at the price of a very challenging ADC. This paper presents an alternative solution where the filter and programmable gain functionality is integrated into a /spl Sigma//spl Delta/ ADC. The novel filtering ADC is realized by adding a high-pass feedback path to a conventional /spl Sigma//spl Delta/ ADC while a compensating low-pass filter in the forward path maintains stability. As such, the ADC becomes highly immune to interferers even if they exceed the maximum allowable input level for the wanted channel. As a consequence, the ADC input range can be programmed dynamically to the level of the wanted signal only. This results in an input-referred dynamic range of 89 dB in 1-MHz bandwidth and an intentionally moderate output signal-to-noise-and-distortion ratio of 46-59 dB (depending on the programmed gain). The merged functionality enables a better overall power/performance balance for the receiver baseband. The design consumes less than 2 mW and active area is 0.14 mm/sup 2/ in a 0.18-/spl mu/m digital CMOS technology.     

Tunable continuous-time bandpass /spl Sigma//spl Delta/ modulators with fractional delays

An analytical design methodology for continuous-time (CT) bandpass (BP) /spl Sigma//spl Delta/ modulators is presented. Second- and fourth-order tunable continuous time BP /spl Sigma//spl Delta/ modulator design equations are presented. A novel /spl Sigma//spl Delta/ loop architecture, where the traditional CT BP loop filter function is replaced with the filter function with fractional delays, is proposed. Validity of the methodology is confirmed by mixed-signal behavioral simulations.     

A fully integrated CMOS DCS-1800 frequency synthesizer

A prototype frequency synthesizer for the DCS-1800 system has been integrated in a standard 0.4 μm CMOS process without any external components. A completely monolithic design has been made feasible by using an optimized hollow-coil inductor low-phase-noise voltage-controlled oscillator (VCO). The frequency divider is an eight-modulus phase-switching prescaler that achieves the same speed as asynchronous dividers. The die area was minimized by using a dual-path active loop filter. An indirect linearization technique was implemented for the VCO gain. The resulting architecture is a fourth-order, type-2 charge-pump phase-locked loop. The measured settling time is 300 μs, and the phase noise is up to -123 dBc/Hz at 600 kHz and -138 dBc/Hz at 3 MHz offset     

A 1-MHz-bandwidth second-order continuous-time quadrature bandpass sigma-delta modulator for low-IF radio receivers

This paper presents a quadrature bandpass /spl Sigma//spl Delta/ modulator with continuous-time architecture. Due to the continuous-time architecture and the inherent anti-aliasing filter, the proposed /spl Sigma//spl Delta/ modulator needs no additional anti-aliasing filter in front of the modulator in contrast to quadrature bandpass /spl Sigma//spl Delta/ modulators with switched-capacitor architectures. The second-order /spl Sigma//spl Delta/ modulator digitizes complex analog I/Q input signals at 1-MHz intermediate frequency and operates within a clock frequency range of 25-100 MHz. The modulator chip achieves a peak signal-to-noise-distortion ratio (SNDR) of 56.7 dB and a dynamic range of 63.8 dB within a 1-MHz signal bandwidth and at a clock frequency of 100 MHz. Furthermore, it provides an image rejection of at least 40 dB. The 0.65-/spl mu/m BiCMOS chip consumes 21.8 mW at 2.7-V supply voltage.     

A fourth-order /spl Sigma//spl Delta/ interface for micromachined inertial sensors

This paper presents the design and implementation of a high-order /spl Sigma//spl Delta/ interface for micromachined inertial sensors, which employs an electronic filter in series with the mechanical sensor element to reject the excessive in-band quantization noise inherently present in state-of-the-art second-order solutions. A fourth-order prototype was fabricated in a standard 0.5-/spl mu/m CMOS process. The active circuit area measures 0.9 mm/sup 2/, and the interface consumes 13 mW from a 5-V supply and achieves resolution of 1/spl deg//s//spl radic/Hz with a gyroscope and 150/spl mu/g//spl radic/Hz with an accelerometer. Comparison between the measured and simulated behavior of the system shows that the contribution of the quantization error to the total noise is negligible.     

A 16-GHz Triple-Modulus Phase-Switching Prescaler and Its Application to a 15-GHz Frequency Synthesizer in 0.18-μm CMOS

A triple-modulus phase-switching prescaler for high- speed operations is presented in this paper. By reversing the switching orders between the eight 45deg-spaced signals generated by the 8 : 1 frequency divider, the maximum operating frequency of the prescaler is effectively enhanced. With the triple-modulus switching scheme, a wide frequency covering range is achieved. The proposed prescaler is implemented in a 0.18-mum CMOS process, demonstrating a maximum operating frequency of 16 GHz without additional peaking inductors for a compact chip size. Based on the high-speed prescaler, a fully integrated integer-N frequency synthesizer is realized. The synthesizer operates at an output frequency from 13.9 to 15.6 GHz, making it very attractive for wideband applications in Ku-band. At an output frequency of 14.4 GHz, the measured sideband power and phase noise at 1-MHz offset are -60 dBc and -103.8 dBc/Hz, respectively. The fabricated circuit occupies a chip area of 1 mm² and consumes a dc power of 70 mW from a 1.8-V supply voltage     

A 900-MHz 1-V CMOS frequency synthesizer

A 900-MHz 1-V frequency synthesizer has been fabricated in a standard 0.35-μm CMOS technology. The frequency synthesizer consists of a divide-by-128/129 and 64/65 dual-modulus prescaler, phase-frequency detector, charge pump, and voltage-doubler circuit with an external voltage-controlled oscillator (VCO) and passive loop filter. The on-chip voltage-doubler circuit converts the 1-V supply voltage to the higher voltage which supplies the prescaler internally. In this way, the 900-MHz 1-V frequency synthesizer with an external VCO can be achieved. The measured phase noise is -112.7 dBc/Hz at a 100-kHz offset from the carrier, and the synthesizer dissipates 3.56 mW (not including VCOs) from a single 1-V supply when the switching frequency of the on-chip voltage doubler is 200 kHz and the power efficiency of the voltage doubler is 77.8%. The total chip area occupies 0.73 mm²     

A 5 GHz CMOS frequency synthesizer with novel phase-switching prescaler and high-Q LC-VCO

A phase-locked loop(PLL) frequency synthesizer with a novel phase-switching prescaler and a high-Q LC voltage controlled oscillator(VCO) is presented.The phase-switching prescaler with a novel modulus control mechanism is much more robust on process variations.The Q factor of the inductor,I-MOS capacitors and varactors in the VCO are optimized.The proposed frequency synthesizer was fabricated by SMIC 0.13μm 1P8M MMRF CMOS technology with a chip area of 1150×2500μm~2.When locking at 5 GHz,the current consumption is 15 mA from a supply voltage of 1.2 V and the measured phase noise at a 1 MHz offset is -122.45 dBc/Hz.