Behavioral level noise modeling and jitter simulation of phase-locked loops with faults using VHDL-AMS

Godambe, N.; Shi, C.-J.R.

doi:10.1109/vtest.1997.600251

Cited by 7 publications

(5 citation statements)

References 32 publications

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“…A methodology for the design of RF circuits in VHDL-AMS starting from flexible specifications and assuring an accurate description of noise and nonlinear effects was proposed in (W. Yang & Yan, 2005). In (Godambe & Shi, 1998) the real behavior of a PLL was modeled using VHDL-AMS adding jitter: the phase noise simulated spectrum was in good agreement with measured results. A top-down design methodology, validated by measurements, was proposed in (V. Nguyen & Naviner, 2005) for the design of a delta-sigma modulator.…”

Section: Vhdl-ams: a Multidisciplinary Language For Multi-resolution mentioning

confidence: 99%

Automotive VHDL-AMS Electro-Mechanics Simulations

Graziano¹,

Roch²

2011

New Trends and Developments in Automotive System Engineering

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Section: Vhdl-ams: a Multidisciplinary Language For Multi-resolution mentioning

confidence: 99%

Automotive VHDL-AMS Electro-Mechanics Simulations

Graziano¹,

Roch²

2011

New Trends and Developments in Automotive System Engineering

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“…Fig. 9 shows a block diagram of a digital PLL [43], [44] in a frequency synthesizer configuration. It consists of a reference …”

Section: B Switched-mode Power Supplymentioning

confidence: 99%

Analogue and mixed-signal extension to SystemC

Al-Junaid

Kázmierski

2005

IEE Proc., Circuits Devices Syst.

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Abstract-This paper presents a new methodology that enables extensions of SystemC to the analogue domain and allows modelling of mixed-signal and mixed energy-domain systems at arbitrary levels of abstraction. The new language constructs support analogue system variables, analogue components and user defined ordinary differential and algebraic equations. Support for digital-analogue interfaces has been provided for smooth integration of digital and analogue parts. Associated issues such as dealing with extremely small and zero time-step sizes have been addressed. A novel implementation of the lock-step mixed-signal synchronisation method to integrate the analogue kernel with the digital one has been proposed. Operation of the extended, mixedsignal simulation platform, named SystemC-A, is demonstrated using a suite of numerically difficult AMS examples including a practical, mixed-signal example of a PLL frequency multiplier with large-signal noise and jitter.

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“…The theoretical jitter analysis of all the main contributors to the output jitter has been done for PLL/DLL systems [6], [7]. Also, the transistor level jitter analysis has been carried out for the charge pump [8] and the voltage controlled delay line [9], [10].…”

Section: Introductionmentioning

confidence: 99%

“…However new design difficulties have arose due to this decreasing transistor dimensions [3]- [5]. As it will be demonstrated, once the delay-locked loop (DLL) architecture and size (number of cells) has been fixed, the actual dimensions of the DLL blocks have a great impact on the performance of the system.The theoretical jitter analysis of all the main contributors to the output jitter has been done for PLL/DLL systems [6], [7]. Also, the transistor level jitter analysis has been carried out for the charge pump [8] and the voltage controlled delay line [9], [10].…”

mentioning

confidence: 99%

Behavioural Modelling of DLLs for Fast Simulation and Optimisation of Jitter and Power Consumption

Barajas

Mateo

González

2010

2010 13th Euromicro Conference on Digital System Design: Architectures, Methods and Tools

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Abstract-This paper presents a behavioural model for fast DLL simulations. The behavioural model includes a modelling of the various noise sources in the DLL that produce output jitter. The model is used to obtain the dependence of the output jitter versus the power consumption. The model exploits the open-loop DLL analysis to reduce simulation time when compared to typical DLL evaluation.Index Terms-DLL, CMOS, behavioural, modelling, Verilog-A, optimisation I. INTRODUCTION During the last years the scaling of the CMOS technology has allowed the integration of full systems on a chip (SoC), including both the digital and analog blocks, as well as the RF front-end [1], [2]. However new design difficulties have arose due to this decreasing transistor dimensions [3]- [5]. As it will be demonstrated, once the delay-locked loop (DLL) architecture and size (number of cells) has been fixed, the actual dimensions of the DLL blocks have a great impact on the performance of the system.The theoretical jitter analysis of all the main contributors to the output jitter has been done for PLL/DLL systems [6], [7]. Also, the transistor level jitter analysis has been carried out for the charge pump [8] and the voltage controlled delay line [9], [10]. This theoretical models have allowed to predict the jitter performance of the DLL blocks and their contribution to the total output jitter. However, their limited accuracy has led to the use of behavioural models based on transistor level simulations, for both PLLs [11] and DLLs [12]. But, even with these latter models, the task to methodically analyse the system for a wide range of dimensions is a very time consuming procedure. This prevents to obtain an accurate model for the DLL jitter performance and the power consumption.In this paper a new fast behavioural model to analyse the impact of the physical transistor dimensions on the overall performance of a DLL is developed. In section II an introduction to the main sources of jitter in a DLL is carried out, while in section III a behavioural model for the DLL blocks is developed. The basis for fast model DLL simulation are explained in section IV. Finally, the results obtained with the introduced model are analysed and discussed in section V.

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Behavioral level noise modeling and jitter simulation of phase-locked loops with faults using VHDL-AMS

Cited by 7 publications

References 32 publications

Automotive VHDL-AMS Electro-Mechanics Simulations

Automotive VHDL-AMS Electro-Mechanics Simulations

Analogue and mixed-signal extension to SystemC

Behavioural Modelling of DLLs for Fast Simulation and Optimisation of Jitter and Power Consumption

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