An 11b 1GS/s ADC with parallel sampling architecture to enhance SNDR for multi-carrier signals

Lin, Yu Chang; Doris, Kostas; Janssen, Éric; Zanikopoulos, A.; Murroni, Alessandro; Weide, G. van der; Hegt, Hans; Roermund, Arthur van

doi:10.1109/esscirc.2013.6649087

Cited by 7 publications

(9 citation statements)

References 8 publications

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“…Afterwards, in [18], a similar design has been evaluated by several simulations for Gaussian distributed signals demonstrating an improvement of about 8 dB in the achievable dynamic range. This paper has been further validated in [19] by realising a parallel sampling architecture on a 65 nm CMOS chip, being evaluated with sinusoidal and multi-carrier 256-quadrature amplitude modulation (QAM) modulated signals, showing improvements of 5 dB for the multi-carrier situation. In addition, in [20] a novel reconstruction scheme based on a gain weighted combining approach has been applied on top of the same parallel ADC architecture.…”

Section: Novel Additions To Dynamic Range Enhancementmentioning

confidence: 97%

“…Instead of a power splitter plus an attenuator [4] or a resistive divider [19], in this paper a directional coupler is utilised because it would maintain good noise figure for the entire receiving chain (lower loss is expected in the mainline), which for RF wideband applications wherein the ADC component is placed as close as possible to the beginning of the receiving chain, and the influence on the overall noise figure would be much lower. In addition, other points could be raised such as in terms of power dissipation that is much stressful for resistive devices.…”

Section: Proposed Scheme For Dynamic Range Improvementmentioning

confidence: 99%

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Improving dynamic range of software‐defined radio receivers for multi‐carrier wireless systems

Cruz

Carvalho

2015

IET Microwaves, Antennas & Propagation

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This study presents an architecture to increase the instantaneous dynamic range of multi-carrier wideband digital receivers. The proposed topology includes a directional coupler followed by two parallel analog-to-digital converters and digital signal processing to reconstruct the signal. It will be shown that the proposed technique is able to increase the dynamic range of software-defined radio (SDR) receivers for multiband signals presenting certain statistical patterns. The concept is validated by simulations and measurements of a real SDR front-end receiver for multiband communications scenario, which will demonstrate improvements in the order of 6 dB when compared to existing alternatives.

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Section: Novel Additions To Dynamic Range Enhancementmentioning

confidence: 97%

Section: Proposed Scheme For Dynamic Range Improvementmentioning

confidence: 99%

Improving dynamic range of software‐defined radio receivers for multi‐carrier wireless systems

Cruz

Carvalho

2015

IET Microwaves, Antennas & Propagation

View full text Add to dashboard Cite

show abstract

“…Therefore, these ADCs are normally thermal noise limited. Circuit techniques for maximizing signal swing are commonly adopted for the purpose of minimizing sampling capacitor sizes [21,22,25,26,29,30,32,33]. Figure 4.10 shows a TI SAR ADC architecture (with hierarchical T/Hs) which is a suitable architecture for designing GHz sampling rate and medium-to-high resolution ADCs [21,22].…”

Section: A Hierarchical Ti-sar Adc Architecturementioning

confidence: 99%

Implementations of the Parallel-Sampling ADC Architecture

Lin

Hegt

Doris

et al. 2015

Analog Circuits and Signal Processing

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This chapter describes circuit implementations of the parallel-sampling ADC architecture presented in Chap. 3. The parallel-sampling architecture is applied to two ADC architectures (a pipeline and a time-interleaving SAR ADC architecture), which are suitable for designing high-speed and medium-to-high resolution ADCs, to improve the ADC power efficiency for multi-carrier signals. Section 4.1 describes the architecture and operation of a 200 MS/s 12-b switchedcapacitor pipeline ADC with a parallel-sampling first stage, which is suitable for broadband multi-carrier receivers for wireless standards such as LTE-advanced and the emerging generation of Wi-Fi (IEEE802.11ac) . A circuit implementation of the parallel-sampling first stage of the pipeline ADC is presented and simulation results are given. Section 4.2 presents the architecture and operation of a 4 GS/s 11 b timeinterleaved ADC with a parallel-sampling frontend stage, which targets wideband direct sampling receivers for DOCSIS 3.0 cable modems . Circuit implementation and simulation of the 4 GS/s parallel-sampling frontend stage are given. Due to the complexity of implementing the proposed 4 GS/s ADC on chip, a two-step design approach was adopted. In Sect. 4.3, a prototype IC of an 11 b 1 GS/s ADC with a parallel sampling architecture is presented, which serves as a first step to validate the parallel-sampling ADC concept and the performance of the high-speed parallelsampling frontend and detection circuits. In future work, the frontend stage of the IC can be interleaved by four times to achieve the aggregate sample rate of 4 GHz of the proposed ADC discussed in Sect. 4.2. Conclusions of this chapter are drawn in Sect. 4.4.

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“…However, the reduction of the sampling capacitor makes the ADC easier to drive and doesn't affect the overall power efficiency [15,22,33] and the required large output signal swing of the ADC driver can be achieved by using the mixed-supply-voltage approach without compromising the speed as proposed in [26,27]. Firstly, while this architecture is intended to improve the ADC power efficiency for multi-carrier signals that have a 'bell-shaped' amplitude probability distribution function (e.g.…”

Section: Sncdr [Db] Optimal Power Back-off [Db]mentioning

confidence: 99%

“…ADCs with GHz sampling rate and medium-to-high resolution (SNR > 50 dB) are mostly based on time-interleaving architecture nowadays [21][22][23][24][25][26][27][28][29][30][31][32][33][34][35][36]. In these ADCs, small sampling capacitors and transistors with low parasitic capacitance are desired in order to achieve high signal bandwidth and low power consumption.…”

Section: A Hierarchical Ti-sar Adc Architecturementioning

confidence: 99%

Power-Efficient High-Speed Parallel-Sampling ADCs for Broadband Multi-carrier Systems

Lin¹,

Hegt²,

Doris³

et al. 2015

Analog Circuits and Signal Processing

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An 11b 1GS/s ADC with parallel sampling architecture to enhance SNDR for multi-carrier signals

Cited by 7 publications

References 8 publications

Improving dynamic range of software‐defined radio receivers for multi‐carrier wireless systems

Improving dynamic range of software‐defined radio receivers for multi‐carrier wireless systems

Implementations of the Parallel-Sampling ADC Architecture

Power-Efficient High-Speed Parallel-Sampling ADCs for Broadband Multi-carrier Systems

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