A fast-settling frequency-presetting PLL frequency synthesizer with process variation compensation and spur reduction

This paper proposes a fast-settling frequency-presetting PLL frequency synthesizer.A mixed-signal VCO and a digital processor are developed to accurately preset the frequency of VCO and greatly reduce the settling time.An auxiliary tuning loop is introduced in order to reduce reference spur caused by leakage current.The digital processor can automatically compensate presetting frequency variation with process and temperature,and control the operation of the auxiliary tuning loop.A 1.2 GHz integer-N synthesizer with 1 MHz reference input Was implemented in a 0.18μm process.The measured results demonstrate that the typical settling time of the synthesizer is less than 3μs,and the phase noise is-108 dBc/Hz@1MHz.The reference spur is-52 dBc.     

射频锁相环型频率合成器的CMOS实现

本论文实现了一个射频锁相环型频率合成器,它集成了压控振荡器、双模预分频器、鉴频鉴相器、电荷泵、各种数字计数器、数字寄存器和控制电路以及与基带电路的串行接口.它的鉴频鉴相频率、输出频率和电荷泵的电流大小都可以通过串行接口进行控制,还实现了内部压控振荡器和外部压控振荡器选择、功耗控制等功能,这些都使得该频率合成器具有极大的适应性,可以应用于多种通信系统中.该锁相环型频率合成器已经采用0.25μm CMOS工艺实现,测试结果表明,该频率合成器使用内部压控振荡器时的锁定范围为1.82GHz~1.96GHz,在偏离中心频率25MHz处的相位噪声可以达到-119.25dBc/Hz.该频率合成器的模拟部分采用2.7V的电源电压,消耗的电流约为48mA.     

使用三位三阶Δ∑调制器的集成1GHz小数频率合成器

本文实现了一个采用三位三阶Δ∑调制器的高频谱纯度集成小数频率合成器.该频率合成器采用了模拟调谐和数字调谐组合技术来提高相位噪声性能,优化的电源组合可以避免各个模块之间的相互干扰,并且提高鉴频鉴相器的线性度和提高振荡器的调谐范围.通过采用尾电流源滤波技术和减小振荡器的调谐系数,在片压控振荡器具有很低的相位噪声,而通过采用开关电容阵列,该压控振荡器达到了大约100MHz的调谐范围,该开关电容阵列由在片数字调谐系统进行控制.该频率合成器已经采用0.18μm CMOS工艺实现,仿真结果表明,该频率频率合成器的环路带宽约为14kHz,最大带内相位噪声约为-106dBc/Hz;在偏离载波频率100kHz处的相位噪声小于-120dBc/Hz,具有很高的频谱纯度.该频率合成器还具有很快的反应速度,其锁定时间约为160μs.     

全集成低噪声CMOS宽带分数分频频率综合器

设计了一款应用于CMMB数字电视广播接收的全集成低噪声宽带频率综合器。采用三阶ΣΔ调制器小数分频器完成高精度的频率输出,使用仅一个低相位噪声的宽带VCO输出频率范围覆盖900~1 600 MHz,产生的本振信号覆盖UHF的数字电视频段(470~790 MHz)。设计中的频率综合器能在所有的频道下保证环路的稳定以及最小的环路性能偏差。测试结果表明,整个频率综合器的带内相位噪声小于-85 dBc/Hz,并且带外相位噪声在1MHz时均小于-121 dBc/Hz,总的频率综合器锁定时间小于300μs。设计在UMC 0.18μm RFCMOS工艺下实现,芯片面积小于0.6 mm2,在1.8 V电源电压的测试条件下,总功耗小于22 mW。     

具有工艺补偿和毛刺消除功能的快速锁定频率预置锁相环频率综合器

This paper proposes a fast-settling frequency-presetting PLL frequency synthesizer. A mixedsignal VCO and a digital processor are developed to accurately preset the frequency of VCO and greatly reduce the settling time. An auxiliary tuning loop is introduced in order to reduce reference spur caused by leakage current. The digital processor can automatically compensate presetting frequency variation with process and temperature, and control the operation of the auxiliary tuning loop. A 1.2 GHz integer-N synthesizer with 1 MHz reference input was implemented in a 0.18 μm process. The measured results demonstrate that the typical settling time of the synthesizer is less than 3 μs, and the phase noise is –108 dBc/Hz@1MHz. The reference spur is –52 dBc.     

一种用于双波段GPS接收机的低功耗宽带CMOS频率合成器

提出了一种用于双波段GPS接收机的宽带CMOS频率合成器.该GPS接收机芯片已经在标准O.18μm射频CMOS工艺线上流片成功,并通过整体功能测试.其中压控振荡器可调振荡频率的覆盖范围设计为2～3.6GHz,覆盖了L1,L2波段的两倍频的频率点.并留有足够的裕量以确保在工艺角和温度变化较大时能覆盖所需频率.芯片测试结果显示,该频率综合器在L1波段正常工作时的功耗仅为5.6mW,此时的带内相位噪声小于-82dBc/Hz,带外相位噪声在距离3.142G载波1M频偏处约为-112dBc/Hz,这些指标很好地满足了GPS接收芯片的性能要求.     

A 1-V 9.7-mW CMOS Frequency Synthesizer for IEEE 802.11a Transceivers

A 1-V CMOS frequency synthesizer is proposed for wireless local area network 802.11a transceivers using a novel transformer-feedback voltage-controlled oscillator (VCO) for low voltage and a stacked frequency divider for low power. Implemented in a 0.18-mum CMOS process and operated at 1-V supply, the VCO measures a phase noise of -140.5 dBc at an offset of 20 MHz with a center frequency of 4.26 GHz and a power consumption of 5.17 mW. Its tuning range is as wide as 920 MHz (23%). By integrating the VCO into a frequency synthesizer, a phase noise of -140.1 dBc/Hz at an offset of 20 MHz is measured at a center frequency of 4.26 GHz. Its output frequency can be changed from 4.112 to 4.352 GHz by switching the 3-bit modulus of the programmable divider. The synthesizer consumes only 9.7 mW and occupies a chip area of 1.28 mm².     

An agile ISM band frequency synthesizer with built-in GMSK datamodulation

In this paper, a high-resolution fractional-N RF frequency synthesizer is presented which is controlled by a fourth-order digital sigma-delta modulator. The high resolution allows the synthesizer to be digitally modulated directly at RF. A simplified digital filter which makes use of sigma-delta quantized tap coefficients is included which provides built-in GMSK pulse shaping for data transmission. Quantization of the tap coefficients to single-bit values not only simplifies the filter architecture, but the fourth-order digital sigma-delta modulator as well. The synthesizer makes extensive use of custom VLSI, with only a simple off-chip loop filter and VCO required. The synthesizer operates from a single 3-V supply, and has low power consumption. Phase noise levels are less than -90 dBc/Hz at frequency offsets within the loop bandwidth. Spurious components are less than -90 dBc/Hz over a 19.6-MHz tuning range     

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 155-mW 50-m vertices/s graphics processor with fixed-point programmable vertex shader for mobile applications

A 36 mm/sup 2/ graphics processor with fixed-point programmable vertex shader is designed and implemented for portable two-dimensional (2-D) and three-dimensional (3-D) graphics applications. The graphics processor contains an ARM-10 compatible 32-bit RISC processor,a 128-bit programmable fixed-point single-instruction-multiple-data (SIMD)vertex shader, a low-power rendering engine, and a programmable frequency synthesizer (PFS). Different from conventional graphics hardware, the proposed graphics processor implements ARM-10 co-processor architecture with dual operations so that user-programmable vertex shading is possible for advanced graphics algorithms and various streaming multimedia processing in mobile applications. The circuits and architecture of the graphics processor are optimized for fixed-point operations and achieve the low power consumption with help of instruction-level power management of the vertex shader and pixel-level clock gating of the rendering engine. The PFS with a fully balanced voltage-controlled oscillator (VCO) controls the clock frequency from 8 MHz to 271 MHz continuously and adaptively for low-power modes by software. The chip shows 50 Mvertices/s and 200 Mtexels/s peak graphics performance, dissipating 155 mW in 0.18-/spl mu/m 6-metal standard CMOS logic process.     

A 2 V 1.8 GHz fully integrated CMOS dual-loop frequency synthesizer

A 2 V 1.8 GHz fully integrated CMOS dual-loop frequency synthesizer is designed in a standard 0.5 /spl mu/m digital CMOS process for wireless communication. The voltage-controlled oscillator (VCO) required for the low-frequency loop is designed using a ring-type VCO and achieves a tuning range of 89% from 356 to 931 MHz and a phase noise of -109.2 dBc/Hz at 600 kHz offset from 856 MHz. With an active chip area of 2000/spl times/1000 /spl mu/m/sup 2/ and at a 2 V supply voltage, the whole synthesizer achieves a tuning range from 1.8492 to 1.8698 GHz in 200 kHz steps with a measured phase noise of -112 dBc/Hz at 600 kHz offset from 1.86 GHz. The measured settling time is 128 /spl mu/s and the total power consumption is 95 mW.     

单片BiCMOS超高频接收机中锁相环的设计

集成电荷泵锁相环的接收芯片工作在ISM频段：290-470MHz,采用AMS0．8μm BiCMOS工艺,npn管的特征频率为12GHz,横向pnp的特征频率为650MHz。锁相环中鉴频鉴相器和电荷泵的设计方案基本消除了死区。压控振荡器采用LC负阻结构,中心振荡频率为433MHz,调谐范围为290-520MHz,频偏为100kHz时的相位噪声约为-98dBC／Hz．分频器采用堆叠式结构以降低功耗,PLL在5V的工作电压下功耗仅为1．4mA。     

GHz band frequency hopping PLL-based frequency synthesizers

In this paper we describe a full-integrated circuit containing all building blocks of a completed PLL-based synthesizer except for low pass filter（LPF）. The frequency synthesizer is designed for a frequency hopping （FH） transceiver operating up to 1.5 GHz as a local oscillator. The architecture of Voltage Controlled Oscillator （VCO） is optimized to get better performance, and a phase noise of -111.85-dBc/Hz @ 1 MHz and a tuning range of 250 MHz are gained at a centre frequency of 1.35 GHz. A novel Dual-Modulus Prescaler（DMP） is designed to achieve a very low jitter and a lower power. The settling time of PLL is 80 μs while the reference frequency is 400 KHz. This monolithic frequency synthesizer is to integrate all main building blocks of PLL except for the low pass filter, with a maximum VCO output frequency of 1.5 GHz, and is fabricated with a 0.18 μm mixed signal CMOS process. Low power dissipation, low phase noise, large tuning range and fast settling time are gained in this design.     

A CMOS frequency synthesizer with an injection-locked frequencydivider for a 5-GHz wireless LAN receiver

A fully integrated 5-GHz phase-locked loop (PLL) based frequency synthesizer is designed in a 0.24 μm CMOS technology. The power consumption of the synthesizer is significantly reduced by using a tracking injection-locked frequency divider (ILFD) as the first frequency divider in the PLL feedback loop. On-chip spiral inductors with patterned ground shields are also optimized to reduce the VCO and ILFD power consumption and to maximize the locking range of the ILFD. The synthesizer consumes 25 mW of power of which only 3.8 mW is consumed by the VCO and the ILFD combined. The PLL has a bandwidth of 280 kHz and a phase noise of -101 dBc/Hz at 1 MHz offset frequency. The spurious sidebands at the center of adjacent channels are less than -54 dBc     

A low power wide-band CMOS PLL frequency synthesizer for portable hybrid GNSS receiver

The design consideration and implementation of a CMOS frequency synthesizer for the portable hybrid global navigation satellite system are presented. The large tuning range is achieved by tuning curve compensation using an improved VCO resonant tank, which reduces the power consumption and obtains better phase noise performance.The circuit is validated by simulations and fabricated in a standard 0.18μm 1P6M CMOS process. Close-loop phase noise measured is lower than -95 dBc at 200 kHz offset while the measured tuning range is 21.5% from 1.47 to 1.83 GHz. The proposed synthesizer including source coupled logic prescaler consumes 6.2 mA current from 1.8 V supply.The whole silicon required is only 0.53 mm~2.     

一个自调谐,自适应的1.9GHz分数/整数频率综合器

本文提出了一个具有自调谐,自适应功能的1.9GHz的分数/整数锁相环频率综合器.该频率综合器采用模拟调谐和数字调谐相结合的技术来提高相位噪声性能.自适应环路被用来实现带宽自动调整,可以缩短环路的建立时间.通过打开或者关断 ΣΔ 调制器的输出来实现分数和整数分频两种工作模式,仅用一个可编程计数器实现吞脉冲分频器的功能.采用偏置滤波技术以及差分电感,在片压控振荡器具有很低的相位噪声;通过采用开关电容阵列,该压控振荡器可以工作在1.7GHz~2.1GHz的调谐范围.该频率综合器采用0.18 μ m,1.8V SMIC CMOS工艺实现.SpectreVerilog仿真表明:该频率综合器的环路带宽约为100kHz,在600kHz处的相位噪声优于-123dBc/Hz,具有小于15 μ s的锁定时间.     

A CMOS self-calibrating frequency synthesizer

A programmable phase-locked-loop (PLL)-based frequency synthesizer, capable of automatically adjusting the nominal center frequency of the voltage-controlled oscillator (VCO) to an optimum value is described. In fully integrated PLLs, the VCO output frequency should be tunable over a wide range of frequencies, covering the desired range of the synthesizer output frequencies, for all processing variations and operating conditions. A wide tuning range realized by making the VCO gain K_o large has the unwanted effect of increasing the phase noise at the output of the VCO, and hence the PLL as well. In this work, the wide tuning range is realized by digital control, with process variability managed through self-calibration. The PLL is only required to pull the oscillator output frequency to account for the digital quantization, temperature variations, and some margin. This allows the K _o to be small, with better noise performance resulting. The prototype self-calibrating frequency synthesizer, capable of operating from 80 MHz to 1 GHz, demonstrates a measured absolute jitter of 20-ps rms at 480-MHz operating frequency. The prototype IC is fabricated in a 0.35-μm 3-V digital CMOS process     

一种宽带低相噪频率合成器的设计方法研究

提出了一种宽带低相噪频率合成器的设计方法.采用了数字锁相技术,该锁相技术主要由锁相环（phase locked loop,PLL）芯片、有源环路滤波器、宽带压控振荡器和外置宽带分频器等构成,实现了10~20 GHz范围内任意频率输出,具有输出频率宽、相位噪声低、集成度高、功耗低和成本低等优点.最后对该PLL电路杂散抑制和相位噪声的指标进行了测试,测试结果表明该PLL输出10 GHz时相位噪声优于-109 dBc/Hz@1 kHz,该指标与直接式频率合成器实现的指标相当.     

A self-calibration technique for wide tuning range PLLs

This paper presents a new calibration technique applicable for wide tuning range phase locked loops (PLLs) using very low gain voltage controlled oscillators (VCO). This technique uses the PLL main loop for the coarse and fine tuning of the VCO. Instead of using two loops which has been reported in previous works, in this work the VCO tuning voltage is used to calibrate the VCO switch capacitor array. Since the proposed calibration circuit operates in a closed loop form, it can be used for channel selection as well as adjusting for process, voltage and temperature variations. In addition, the calibration circuit has been used to set the VCO tail current in order to optimize VCO phase noise. A prototype frequency synthesizer has been designed in 0.18-μm CMOS process to work for a frequency range from 2.4 to 2.72 GHz. Simulation results show that using the proposed technique, a spur level of ?60 dB at 5 MHz offset from carrier was achieved while having negligible power overhead.     

A GMSK modulator using a ΔΣ frequencydiscriminator-based synthesizer

This paper describes a new transmitter architecture suitable for wideband GMSK modulation. The technique uses direct modulation of ΔΣ frequency discriminator (ΔΣFD)-based synthesizer to produce the modulated RF signal without any up-conversion. Digital equalization is used to extend the modulation data rate far beyond the synthesizer closed-loop BW. A prototype 1.9-GHz GSM transmitter was constructed consisting of a ΔΣFD-based synthesizer and a digital transmit filter. The synthesizer consists of an 0.8-μm BiCMOS ΔΣFD chip, a digital signal processor FPGA, and an off-chip D/A converter, filter, and VCO. Measured results, using 271-kbit/s GSM modulation, demonstrate data rates well in excess of the 30-kHz synthesizer closed-loop BW are possible with digital equalization. Without modulation, the synthesizer exhibits a -76-dBc spurious noise level and a close-in phase noise of -74 dBc/Hz