Phase Locked Loop Test Methodology

Phase locked loops are incorporated into almost every large-scale mixed signal and digital system on chip (SOC). Various types of PLL architectures exist including fully analogue, fully digital, semi-digital, and software based. Currently the most commonly used PLL architecture for SOC environments and chipset applications is the Charge-Pump (CP) semi-digital type. This architecture is commonly used for clock synthesis applications, such as the supply of a high frequency on-chip clock, which is derived from a low frequency board level clock. In addition, CP-PLL architectures are now frequently used for demanding RF (Radio Frequency) synthesis, and data synchronization applications. On chip system blocks that rely on correct PLL operation may include third party IP cores, ADCs, DACs and user defined logic (UDL). Basically, any on-chip function that requires a stable clock will be reliant on correct PLL operation. As a direct consequence it is essential that the PLL function is reliably verified during both the design and debug phase and through production testing. This chapter focuses on test approaches related to embedded CP-PLLs used for the purpose of clock generation for SOC. However, methods discussed will generally apply to CP-PLLs used for other applications

Architectures for RF Frequency synthesizers

Frequency synthesizers are an essential building block of RF communication products. They can be found in traditional consumer products, in personal communication systems, and in optical communication equipment. Since frequency synthesizers are used in many different applications, different performance aspects may need to be considered in each case. The main body of the text describes a conceptual framework for analyzing the performance of PLL frequency synthesizers, and presents optimization procedures for the different performance aspects. The analysis of the PLL properties is performed with the use of the open-loop bandwidth and phase margin concepts, to enable the influence of higher-order poles to be taken into account from the beginning of the design process. The theoretical system analysis is complemented by descriptions of innovative system and building block architectures, by circuit implementations in bipolar and CMOS technologies, and by measurement results. Architectures for RF Frequency Synthesizers contains basic information for the beginner as well as in-depth knowledge for the experienced designer. It is widely illustrated with practical design examples used in industrial products.\ud Written for:\ud Electrical and electronic engineer

FULLY INTEGRATED HIGH-FREQUENCY CLOCK GENERATION AND SYNCHRONIZATION TECHINIQUES

Department of Electrical EngineeringThis thesis presents clock generation and synchronization techniques for RF wireless communication. First, it deals with voltage-controlled oscillators (VCOs) for local oscillators (LO) in transceivers, and secondly delay-locked loops for synchronization. For the high-performance LO, VCO is one of the key blocks. LC VCOs and ring VCOs are commonly-used types. Their characteristics are varied for different frequency bands. In this thesis, two types of VCOs, LC VCO and ring VCO, are presented with specific applications. For the multi-clock generator which could be used for carrier aggregation or frequency hopping, ring-type digitally controlled oscillator (DCO) was designed covering 900-1200 MHz with -165 dB FOM. For the multi-band frequency synthesizer which could be used for 5G communication with backward compatibility, three LC VCOs are designed which frequency range of 25-30 GHz for 5G, 5.2-6.0 GHz for LTE, 2.7-4.2 GHz for 2G-3G communication, respectively. For the clock synchronization in RF communications, a delay-locked loop (DLL) using a digital-to-analog converter (DAC) based band-selecting circuit (BSC) was presented to achieve a wide harmonic-locking-free frequency range. The BSC used the proposed exponential digital-to-analog converter (EDAC) to generate a collection of initial control voltages which follow a sequence of geometric with satisfying the condition for preventing harmonic locking problem. Therefore, the BSC can cover a much wider frequency range which is free from harmonic locking problem compared to initial band selection techniques using conventional, linear DAC (LDAC) that have a set of control voltages of arithmetic sequence. In this thesis, the DLL was implemented in a 65-nm CMOS process, and it had a measured frequency range from 100 to 1500 MHz which range is free from harmonic locking. The measure rms jitter and 1-MHz phase noise at 1000 MHz were 1.99 ps and ?28 dBc/Hz, respectively. The DLL consumes 5.5 mW and its active area was 0.052 mm2.clos