scholarly journals A 1.2-V 6-GHz Dual-Path Charge-Pump PLL Frequency Synthesizer for Quantum Control and Readout in CMOS 65-nm Process

2020 ◽  
Author(s):  
Vamshi Manthena ◽  
Sandeep Miryala ◽  
Grzegorz Deptuch ◽  
Gabriella Carini
Keyword(s):  
Quantum Control ◽  
Frequency Synthesizer ◽  
Charge Pump ◽  
Charge Pump Pll ◽  
Pll Frequency Synthesizer

scholarly journals RHBD Charge Pump PLL based 2.4 GHz Frequency Synthesizer

2019 ◽  
Vol 8 (2) ◽  
pp. 3984-3995
Keyword(s):  
Phase Noise ◽  
Frequency Synthesizer ◽  
Fault Tolerant ◽  
Setting Time ◽  
Charge Pump ◽  
Radiation Environment ◽  
Ieee 802.11B ◽  
Standard Requirement ◽  
Charge Pump Pll ◽  
Radiation Hard

Frequency Synthesizer forms the heart of electronic communication system. Phase Locked Loop (PLL) based Frequency Synthesizers over the years has become the ubiquitous solution for generation of stable clock source. But it is a challenging task to design and develop PLL to be used in radiation environment such as in satellites, space systems and military electronics. Since impact of radiation strike on PLL is said to introduce transient faults resulting in increased timing jitter, distortion in phase, and bit flips. One or more of the above said effects can initiate false triggering which may result in incorrect data to be latched, loss of synchronization in data processing and networking. This may lead to catastrophic effect. Hence, as the stability of frequency synthesizer is of vital importance, there is a stressful need for design of radiation hard, fault tolerant frequency synthesizer. With this motivation, in this paper, a radiation hard CMOS Charge Pump PLL is designed to synthesize a 2.4GHz frequency source using 20MHz reference input frequency. The proposed radiation hard PLL design uses a hybrid Radiation Hardening By Design (RHBD) fault tolerant technique combined with redundancy, hence offering a twofold level of fortification from radiation spikes. Cadence tool was used for simulation. The PLL designed has exhibited satisfactory performance. The RHBD Charge Pump PLL in presence of radiation strike resulted in rms jitter of 128.9ps, phase noise of -94.03dbc/Hz and settling time of 159ns against the IEEE 802.11b/g standard requirement of 250ps jitter, -110dbc/Hz phase noise and 10us setting time.

A low power fast-settling frequency-presetting PLL frequency synthesizer

2010 ◽  
Vol 31 (8) ◽  
pp. 085002 ◽  
Author(s):  
Geng Zhiqing ◽  
Yan Xiaozhou ◽  
Lou Wenfeng ◽  
Feng Peng ◽  
Wu Nanjian
Keyword(s):  
Low Power ◽  
Frequency Synthesizer ◽  
Pll Frequency Synthesizer ◽  
Fast Settling

scholarly journals ANALYSIS OF FREQUENCY SYNTHESISERS FOR MULTISTANDART WIRELESS TRANSCEIVER / DAŽNIO SINTEZATORIŲ DAUGIASTANDARČIAMS BEVIELIO RYŠIO SIŲSTUVAMS IR IMTUVAMS ANALIZĖ

2016 ◽  
Vol 8 (3) ◽  
pp. 302-307 ◽  
Author(s):  
Marijan Jurgo ◽  
Romualdas Navickas
Keyword(s):  
Figure Of Merit ◽  
Frequency Synthesizer ◽  
Cmos Technology ◽  
Wireless Transceivers ◽  
Frequency Locking ◽  
Wireless Transceiver ◽  
Loop Bandwidth ◽  
Charge Pump Pll ◽  
Chip Size ◽  
Better Than

Frequency synthesiser is one of most important blocks in wire-less transceiver. Generally phase locked loop (PLL) is used as frequency synthesiser in multistandart wireless transceivers. Two main structures of PLL are conventional (mixed, charge pump) PLL and All-Digital PLL. Newest works, related to design of conventional PLLs, are oriented to minimise power consumption and chip size, increase loop bandwidth and decrease frequency locking time. Main focus of All-Digital PLLs design is to reduce quantisation noise. New figure of merit (FOM) is proposed to compare frequency synthesisers of different type. This function depends on all main parameters of frequency synthesizer for multistandart transceiver: phase noise, operation frequency, frequency tuting range, power dissipation, used area of silicon. Used CMOS technology is also assessed in proposed FOM. From the calsulated FOM value for newest published frequency synthesisers it is seen, that in nanometric technologies All-Digital frequency synthesisers are superior to conventional synthesisers. Although, performance of conventional frequency synthesisers, implemented in larger technologies (0.18 µm ir 0.13 µm), is comparable or better than performance of All-Digital synthesisers. Dažnio sintezatorius yra vienas iš svarbiausių blokų bevielio ryšio siųstuvuose-imtuvuose. Kaip dažnio sintezatorius daugiastandarčiams bevielio ryšio siųstuvams ir imtuvams dažniausiai yra naudojama fazės derinimo kilpa (FDK). Dvi pagrindinės FDK struktūros yra klasikinė (mišri, krūvio pompos) ir visiškai skaitmeninė fazės derinimo kilpa. Naujausiuose darbuose, susijusiuose su klasikinės FDK projektavimu, siekiama mažinti galią ir plotą, dažnio suderinimo trukmę, platinti praleidžiamų dažnių ruožą. Pagrindinis dėmesys projektuojant visiškai skaitmenines FDK skiriamas kvantavimo triukšmui mažinti. Įvairių struktūrų ir tipų dažnio sintezatoriams palyginti yra siūloma nauja kokybės funkcija (FOM). Ši funkcija priklauso nuo visų pagrindinių sintezatoriaus, tinkančio daugiastandarčiams siųstuvams-imtuvams, parametrų: fazinio triukšmo, darbinio dažnio, dažnio perderinimo ruožo pločio, vartojamosios galios, luste užimamo ploto. Taip pat įvertinama naudojama KMOP technologija. Iš apskaičiuotų kokybės funkcijos rezultatų naujausiems publikuotiems dažnio sintezatoriams matyti, kad nanometrinėse technologijose visiškai skaitmeninės struktūros dažnio sintezatoriai yra pranašesni už klasikinius, tačiau didesnėse (0,18 μm ir 0,13 μm) technologijose įgyvendinti klasikiniai dažnio sintezatoriai yra lygiaverčiai arba pranašesni už visiškai skaitmeninius sintezatorius.

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