A 1.78–3.05?GHz fractional-N frequency synthesizer with power reduced multi-modulus divider

Nowadays, multi-band frequency synthesizers are very popular for their compatibility, which lowers the chip cost. In this article, a low power 2.4?GHz broadband fractional-N frequency synthesizer based on ???C?? modulation is presented. A novel power reduced multi-modulus divider based on 2/3 divider cells is presented. The ??mod?? signals are employed to dynamically control the current of the end-of-cycle logic blocks in 2/3 divider cells. When the end-of-cycle logic blocks have no contribution to the divider operation, they are turned off to save power. The saved power is more than 30% in the desired division ratio range. A dual-band voltage controlled oscillator with switched capacitor arrays is designed to cover a wide tuning range. Other circuits such as phase frequency detector, charge pump and loop filter are also integrated on the chip. The whole frequency synthesizer has been fabricated in Chartered 0.18???m RF CMOS process. Tested results show it covers the tuning range from 1.78 to 3.05?GHz, with phase noise smaller than ?85 dBc/Hz at 100?kHz offset, and smaller than ?115 dBc/Hz at 3?MHz offset. Its power consumption is only 9.2?mW under 1.8?V supply voltage, and the chip occupies an area of 1.2?mm?×?1.3?mm.     

An integrated 0.38–6 GHz, 9–12 GHz fully differential fractional-N frequency synthesizer for multi-standard reconfigurable MIMO communication application

A wide-band fully differential fractional-N frequency synthesizer for multi-standard application is presented. The single fully differential LC–VCO with 28.5 % tuning rang and a set of dividers, quadrature self-mixer are designed to accomplish the multi-frequency bands with the frequency band from 0.38 to 6 GHz and from 9.0 to 12 GHz. It covers several wireless standards. A novel high isolation multiplexer is presented to achieve the frequency band selection. This chip was implemented with 65 nm CMOS technology and the maximum consumption is 20.05 mA from 1.2 V power supply. It occupies an active area of 1.5 mm². The measured typical phase noise of the frequency synthesizer is ?114.6 dBc/Hz from 1 MHz offset for 4.85 GHz output.     

An integrated 8-12 GHz fractional-N frequency synthesizer in SiGe BiCMOS for satellite communications

We present an integrated fractional-N low-noise frequency synthesizer for satellite applications. By using two integrated VCOs and combining digital and analog tuning techniques, a PLL lock range from 8 to 12 GHz is achieved. Due to a small VCO fine tuning gain and optimized charge pump output biasing, the phase noise is low and almost constant over the tuning range. All 16 sub-bands show a tuning range above 900 MHz each, allowing temperature compensation without sub-band switching. This makes the synthesizer robust against variations of the device parameters with process, supply voltage, temperature and aging. The measured phase noise is ?87 dBc/Hz and ?106 dBc/Hz at 10 kHz and 1 MHz offset, respectively. In integer-N mode, phase noise values down to ?98 dBc/Hz at 10 kHz and ?111 dBc/Hz at 1 MHz offset, respectively, were measured.     

A highly linear and fully-integrated FMCW synthesizer for 60 GHz radar applications with 7 GHz bandwidth

A highly linear and fully-integrated frequency-modulated continuous-wave (FMCW) generator based on a fractional-N phase-locked loop (PLL) that is able to synthesize modulation schemes in 57–64 GHz range is proposed in this paper. The fractional-N PLL employs Colpitts voltage-controlled oscillator (VCO) at 60 GHz with 13.5% tuning range. Automatic amplitude and frequency calibrations are implemented to avoid drifts due to process, voltage and temperature variations and to set the center frequency of the VCO. Five-stage multi-modulus divider is used for division ratio switching, controlled by the sigma-delta (\(\Sigma \Delta\)) modulator MASH 1-1-1. The frequency sweep (chirp) bandwidth and duration are fully programmable via serial peripheral interface allowing up to 16 different chirps in complex modulation scheme. The PLL reference signal is 250 MHz provided by external low-noise signal generator which is also used for digital modules clock. The overall PLL phase noise is lower than ?80 dBc/Hz at 10 kHz offset and the chirp linearity is better than 0.01%. The complete FMCW synthesizer is implemented and verified as a stand-alone chip in a commercially available SiGe HBT 130 nm BiCMOS technology. The total chip area is \(2.04\,\text {mm}^2\), and the total power consumption is 280 mW.     

A 55 nm CMOS △∑fractional-N frequency synthesizer for WLAN transceivers with low noise filters

A fully integrated ΔΣ fractional-N frequency synthesizer fabricated in a 55 nm CMOS technology is presented for the application of IEEE 802.11b/g wireless local area network(WLAN) transceivers.A low noise filter,occupying a small die area,whose power supply is given by a high PSRR and low noise LDO regulator,is integrated on chip.The proposed synthesizer needs no off-chip components and occupies an area of 0.72 mm2 excluding PAD.Measurement results show that in all channels,the phase noise of the synthesizer achieves -99 dBc/Hz and -119 dBc/Hz in band and out of band respectively with a reference frequency of 40 MHz and a loop bandwidth of 200 kHz.The integrated RMS phase error is no more than 0.6°.The proposed synthesizer consumes a total power of 15.6 mW.     

A 0.9–5.4 GHz wideband fast settling frequency synthesizer for 5G based consumer services

In this paper, a frequency synthesizer, based on a type-2, third order phase locked loop (PLL), covering the frequency range of 0.9–5.4 GHz using three voltage controlled oscillators, is implemented using a 0.13-\(\upmu \hbox {m}\) CMOS technology. The PLL has three modes of operation—a high bandwidth mode, a low bandwidth mode and a dynamic mode, in which the bandwidth dynamically changes from a low to a high value, during a frequency jump, and reverts back to low value, once the PLL settles. With a proper choice of bandwidth and timing synchronization during a frequency jump, a worst-case settling time of 3-\(\upmu \hbox {s}\) has been obtained, which is one of the lowest in reported literature. The input clock of the PLL is set to 100 MHz, but it can go as low as 25 MHz without having any effect on its settling time. The PLL consumes 24 mW of power and occupies 0.8 mm\(^2\) of active area.This PLL is expected to be specially useful in wide-bandwidth cognitive radios that require large and fast transitions in the frequency of operation.     

A △∑ fractional-N frequency synthesizer for FM tuner using low noise filter and quantization noise suppression technique

A △∑ fractional-N frequency synthesizer fabricated in a 130 nm CMOS technology is presented for the application of an FM tuner. A low noise filter, occupying a small die area and decreasing the output noise, is integrated on a chip. A quantization noise suppression technique, using a reduced step size of the frequency divider, is also adopted. The proposed synthesizer needs no off-chip components and occupies an area of 0.7 mm2. The in-band phase noise （from 10 to 100 kHz） below -108 dBc/Hz and out-of-band phase noise of -122.9 dBc/Hz （at 1 MHz offset） are measured with a loop bandwidth of 200 kHz. The quantization noise suppression technique reduces the in-band and out-of band phase noise by 15 dB and 7 dB respectively. The integrated RMS phase error is no more than 0.48°. The proposed synthesizer consumes a total power of 7.4 mW and the frequency resolution is less than 1 Hz.     

A low power CMOS phase-switching prescaler for 1.8–2.4 GHz wireless communications

A divide-by-31/32 phase switching prescaler with a simple divide-by-4 multi-phase ring counter is presented. By using this divide-by-4 unit, a low power consumption is obtained while a wide range operation is maintained. Fabricated with a standard 0.18 μm CMOS technology, the prescaler can work properly from 1.8 to 3.1 GHz with a maximum current dissipation of 1.3 mA from a 1.8 V supply voltage. It can cover most of wireless communication standards in 1.8/1.9 GHz and 2.4 GHz bands.     

CMOS implementation of a 1.6 GHz low voltage low phase noise quadrature output frequency synthesizer with automatic amplitude control

This article presents the design of a 1.2 V CMOS low phase noise quadrature output frequency synthesizer (FS) to be used for a GPS tuner application. Special reference is made to the design of a wide tuning range quadrature output voltage-controlled oscillator which is equipped with an automatic amplitude controller. It exhibits a phase noise response of less than −115 dBc/Hz at an offset of 1 MHz from the carrier and has a tuning range of over 36%. The effect of the automatic amplitude control is shown to improve phase noise at high oscillation frequencies and its noise has a negligible effect on the phase noise response even at low offset frequencies from the carrier. Preliminary analysis is presented showing the negligible effect of a DC–DC converter on the spurious level of the FS, included to permit the use of low sensitivity varactors. Design guidelines for reducing both the loop noise and the AM-to-PM conversion factors of the oscillator are also given. The design was made using the STMicroelectronics 0.13 μm HCMOS9-RF technology design kit.     

A 400 MHz–1.5 GHz all digital integer-N PLL with a reference spur reduction technique

In this Letter, 400 MHz–1.5 GHz all digital integer-N PLL with a reference spur reduction is proposed. A reference spur is occurred by updating DCO control code at every reference clock period. To reduce a reference spur component, the phase detector which transfers phase error information only when phase error is detected has been designed. The measured clock jitter is 2.528 ps_rms at 1.5 GHz operation, and 3.991 ps_rms at 400 MHz operation. The ADPLL occupies 0.088 mm², and consumes 1.19 mW at 1.5 GHz. This ADPLL is implemented in 65 nm CMOS technology.     

A low phase noise and low power 3–5 GHz frequency synthesizer in 0.18 µm CMOS technology

A low power frequency synthesizer for WLAN applications is proposed in this paper. The NMOS transistor-feedback voltage controlled oscillator (VCO) is designed for the purpose of decreasing phase noise. TSPC frequency divider is designed for widening the frequency range with keeping low the power consumption. The phase frequency detector (PFD) with XOR delay cell is designed to have the low blind and dead zone, also for neutralizing the charge pump (CP) output currents; the high gain operational amplifier and miller capacitors are applied to the circuit. The frequency synthesizer is simulated in 0.18 µm CMOS technology while it works at 1.8 V supply voltage. The VCO has a phase noise of −136 dBc/Hz at 1 MHz offset. It has 10.2% tuning range. With existence of a frequency divider in the frequency synthesizer loop the output frequency of the VCO can be divided into the maximum ratio of 18. It is considered that the power consumption of the frequency synthesizer is 4 mW and the chip area is 10,400 µm².     

A 6–9 GHz UWB balun-LNA employing current-reuse with preamplifier and CCC buffer

This paper presents a high-gain and low-power balun-LNA for ultra-wideband receiver operating in the upper band (6–9 GHz). Common gate (CG) preamplifier in front of the active balun can provide input matching and suppress noise from the follow-up stages. Active balun shares bias current with the CG stage to reduce power consumption. Capacitor-cross-coupled buffer is cascaded for signal amplitude and phase correction. The balun-LNA is fabricated in TSMC 130 nm CMOS technology and it consumes 5.5 mA current from a 1.3-V supply including buffer. This balun-LNA can achieve wideband gain from 6.5 to 9.0 GHz and the maximum gain is 23 dB. The input return loss is better than 20 dB from 6.5 to 9.0 GHz. The core area of the LNA is 0.53 mm². Simulated noise figure of the LNA is under 3.2 dB.     

A 60 GHz phased array with measurement and de-embedding techniques

We present a 60 GHz phased array system that combines several key technologies to realize 10 GHz bandwidth coverage. Particularly, a tightly coupled dipole array centered at 60 GHz is designed and tested for its wideband performance. The tightly coupled dipole elements offer excellent wideband behavior of 10 GHz with voltage standing wave ratio?<?3 with scanning to 45°, as well as low cost printed circuit board fabrication. Additionally, we demonstrate a measurement setup with de-embedding procedure to measure gain at the antenna feed point. A feeding structure was designed and fabricated for de-embedding gain pattern measurements. Recovered measurements are shown to be in agreement with simulation.     

Modeling and characterization of a 5.2 GHz VCO for UWB applications in 0.13 μm CMOS process

This paper describes a 5.2 GHz voltage-controlled oscillator (VCO) as a key component in RF transceivers. The circuit includes a complementary cross-coupled MOSFET as a negative conductance, beside a tank circuit which consists of an optimal on-chip spiral inductor (L), and an accumulation mode MOS varactor (C(V)). A model for phase noise and figure merit is introduced and verified through simulation in a standard 0.13 μm CMOS process. The VCO core drew a 4.2 mA of current from a 1.2 V power supply and a phase noise of −98.5 dBc/Hz at 1 MHz offset from the 5.2 GHz carrier was calculated. The whole performance of the circuit specifically the tuning range was found to be 26%.     

A 90–96 GHz CMOS down-conversion mixer with high conversion gain and excellent LO–RF isolation

A 90–96 GHz down-conversion mixer for 94 GHz image radar sensors using standard 90 nm CMOS technology is reported. RF negative resistance compensation technique, i.e. NMOS LC-oscillator-based RF transconductance (GM) stage load, is used to increase the output impedance and suppress the feedback capacitance C_gd of RF GM stage. Hence, conversion gain (CG), noise figure (NF) and LO–RF isolation of the mixer can be enhanced. The mixer consumes 15 mW and achieves excellent RF-port input reflection coefficient of ?10 to ?36.4 dB for frequencies of 85–105 GHz. The corresponding -10 dB input matching bandwidth is 20 GHz. In addition, for frequencies of 90–96 GHz, the mixer achieves CG of 6.3–9 dB (the corresponding 3-dB CG bandwidth is greater than 6 GHz) and LO–RF isolation of 40–45.1 dB, one of the best CG and LO–RF isolation results ever reported for a down-conversion mixer with operation frequency around 94 GHz. Furthermore, the mixer achieves an excellent input third-order intercept point of 1 dBm at 94 GHz. These results demonstrate the proposed down-conversion mixer architecture is very promising for 94 GHz image radar sensors.     

5.18–7.42 GHz LC-VCO in subthreshold regime with low power low phase noise and immunity to PVT variations in 130 nm CMOS technology

In this paper, we propose an LC-VCO using automatic amplitude control and filtering technique to eliminate frequency noise around 2\(\omega _0\). The LC-VCO is designed with TSMC 130 nm CMOS RF technology, and biased in subthreshold regime in order to get more negative transconductance to overcome the losses in the LC-Tank and achieve less power consumption. The designed VCO operates at 5.17 GHz and can be tuned from 5.17 to 7.398 GHz, which is corresponding to 35.5% tuning range. The VCO consumes through it 495–440.5 \(\upmu\)W from 400 mV dc supply. This VCO achieves a phase noise of \(-\,122.3\) and \(-\,111.7\) dBc/Hz at 1 MHz offset from 5.17 and 7.39 GHz carrier, respectively. The calculated Figure-of-merits (FoM) at 1 MHz offset from 5.17 and 7.39 GHz is \(-\,199.7\) and \(-\,192.4\) dBc/Hz, respectively. And it is under \(-\,190.5\) dBc/Hz through all the tuning range. The FoM\(_T\) at 1 MHz offset from 5.17 GHz carrier is \(-\,210.6\) dBc/Hz. The proposed design was simulated for three different temperatures (\(-\,55\), 27, \(125\,^{\circ }\hbox {C}\)), and three supply voltages (0.45, 0.4, 0.35 V), it was concluded that the designed LC-VCO presents high immunity to PVT variations, and can be used for multi-standard wireless LAN communication protocols 802.11a/b/g.