Franck Badets scite author profile

A complete analysis of the spur characteristics of edge-combining delay-locked loop (DLL)-based frequency multipliers is presented in this brief. The novelty of this analysis is the fact that it can be used to estimate the effect of both the in-lock error and the delay-stage mismatch on the spurious level of the frequency multiplier with low computational complexity. In addition, a way to reduce the mismatch between the delay cells in the delay line is discussed via an analytic model and verified by the implementation of a delay cell in a 65-nm CMOS process.Index Terms-Delay mismatch, delay-locked loop (DLL), frequency synthesis, in-lock error, spurious level.

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A 17.5-to-20.94GHz and 35-to-41.88GHz PLL in 65nm CMOS for wireless HD applications

Richard

Siligaris

Badets

et al. 2010

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This work shows a complete PLL that is integrated in standard industrial 65nm CMOS technology. This frequency synthesizer is fully compliant with IEEE 802.15.3c normalization [1][2][3][4]. This PLL delivers a quadrature LO signal around 20GHz and a differential LO signal around 40GHz and has 17.9% tuning range. The wide tuning range of 17.9% permits to cover the full IEEE 802.15.3c band with industrial margin. The phase noise is -100dBc/Hz at 1MHz offset and the total power dissipation is only 80mW including the output buffers and amplifiers. Short-range wireless multi-Gb/sec communication systems use the mm-wave band of 57GHz to 66GHz, according to the IEEE 802.15.3c normalization. The frequency synthesis is one of the key elements for these transceivers. Indeed, one must take into account the antagonist tradeoff between large band tuning range of the frequency synthesizer and phase noise performance. In transceivers using super-heterodyne architecture with double conversion, the frequency synthesizer signal f LO can be equal to 2f RF /3 and f RF /3. In this case, to cover the four channels of the IEEE 802.15.3c normalization, the frequency synthesizer has to deliver a first local oscillator (LO) signal between 19.44GHz and 21.6GHz and a second LO signal between 38.88GHz and 43.2GHz, respectively. This architecture offers a good trade off between the required large frequency tuning range (>15%) and low phase noise (<-95dBc/Hz).The PLL architecture is depicted in Fig. 13.5.1. It is composed of a Push-Push Quadrature-Voltage-Controlled-Oscillator (QVCO) that delivers two 0°/90° LO signals around 20GHz and a harmonic signal around 40GHz. The QVCO is followed by a frequency divider chain with a division ratio varying from 640 to 1240. Next, the Phase/Frequency Detector (PFD) compares the VCO's divided signal to an external 36MHz reference signal which is divided by two. Finally, a Charge Pump (CP) followed by a 3 rd order Loop Filter (LF) controls the QVCO's oscillation frequency. Figure 13.5.2 shows the schematic of the QVCO. It is based on two cross coupled CMOS VCOs (MI_1 … MI_4 and MQ_1 … MQ_4). In order to generate the 0°/90° oscillation signals each basic VCO cell is coupled by two NMOS transistors (MI_5, MI_6 and MQ_5, MQ_6). The global QVCO oscillates around 20GHz. Each cell's resonator includes a single octagonal integrated inductance and a bank of varactors. The bank uses many varactors for oscillation frequency control. One of the varactors is connected to the loop filter (LF) voltage control (analog varactor) and the others are switched ON and OFF with the help of a 4 bits digital control (digital varactors). This technique helps to split the required oscillation band into sub-bands and to reduce the oscillator's gain for better PLL global stability. The oscillation sub-bands overlap between them thanks to a judicious choice of each of the varactors size. The required 40GHz signal is collected at the current source of the coupling transistors with the help of two shortended quarter wave transmission line...

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A 500-MHz ΣΔ phase-interpolation direct digital synthesizer

Finateu

Miro-Panades

Boissieres

et al. 2007

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A Σ∆ phase-interpolation direct digital synthesizer (DDS) is presented. This DDS generates frequencies from 400 MHz up to 500 MHz. Phase interpolation uses dual slope integration on a single capacitor and current is provided by a digital to analog converter (DAC). The Σ∆ enables high frequency resolution and shapes quantization noise. The DDS has been integrated on a 65-nm CMOS STMicroelectronics technology. The power consumption is about 29 mW without buffers under 1.2 V for a 500-MHz operating frequency.

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GMSK modulation of subharmonic injection locked oscillators

Finateu

Bégueret

Deval

et al.

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Franck Badets

A GHz Spintronic-Based RF Oscillator

Analysis of the Spur Characteristics of Edge-Combining DLL-Based Frequency Multipliers

A 17.5-to-20.94GHz and 35-to-41.88GHz PLL in 65nm CMOS for wireless HD applications

A 500-MHz ΣΔ phase-interpolation direct digital synthesizer

GMSK modulation of subharmonic injection locked oscillators

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About

Franck Badets

A GHz Spintronic-Based RF Oscillator

Analysis of the Spur Characteristics of Edge-Combining DLL-Based Frequency Multipliers

A 17.5-to-20.94GHz and 35-to-41.88GHz PLL in 65nm CMOS for wireless HD applications

A 500-MHz &#x03A3;&#x0394; phase-interpolation direct digital synthesizer

GMSK modulation of subharmonic injection locked oscillators

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Product

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A 500-MHz ΣΔ phase-interpolation direct digital synthesizer