4 research outputs found
A Subthreshold Current-Sensing Sigma-Delta Modulator for Low-Voltage and Low-Power Sensor Interfaces
A continuous-time (CT) ΣΔ modulator for sensing and direct analog-to-digital conversion of nA-range (subthreshold) currents is presented in this work. The presented modulator uses a subthreshold technique based on subthreshold source-coupled logic cells to efficiently convert subthreshold current to digital code without performing current-to-voltage conversion. As a benefit of this technique, the current-sensing CT ΣΔ modulator operates at low voltage and consumes very low power, which makes it convenient for low-power and low-voltage current-mode sensor interfaces. The prototype design is implemented in a 0.18 µm standard complementary metal-oxide semiconductor technology. The modulator operates with a supply voltage of 0.8 V and consumes 5.43 μW of power at the maximum bandwidth of 20 kHz. The obtainable current-sensing resolution ranges from effective number of bits (ENOB) = 7.1 bits at a 5 kHz bandwidth to ENOB = 6.5 bits at a 20 kHz bandwidth (ENOB). The obtained power efficiency (peak FoM = 1.5 pJ/conv) outperforms existing current-mode analog-to-digital converter designs and is comparable with the voltage-mode CT ΣΔ modulators. The modulator generates very low levels of switching noise thanks to CT operation and subthreshold current-mode circuits that draw a constant subthreshold current from the voltage supply. The presented modulator is used as a readout interface for sensors with current-mode output in ultra low-power conditions and is also suitable to perform on-chip current measurements in power management circuits
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Power Efficient Architectures for High Accuracy Analog-to-Digital Converters
Incremental ADCs (IADCs) have found wide applications in sensor interface circuitry since, compared to ∆Σ ADCs, they provide low-latency high-accuracy conversion and easy multiplexing among multiple channels. On the other hand, continuous-time ∆Σ ADCs (CTDSM) have been receiving more and more attention as a power-efficient solution in targeting medium to high accuracy over wider range of signal bandwidth (tens of MHz). In this dissertation, novel configurations have been explored in both architectures for power-efficient and high-accuracy data conversion.
First, a multi-step incremental ADC (IADC) using multi-slope extended counting technique is described. Only one active integrator is used in the three-step conversion cycle. The accuracy of the IADC is extended by having it configured as multi-slope ADCs in two additional steps. The proposed IADC uses the same circuitry as a first-order IADC (IADC1), but it exhibits as good efficiency as its second-order ∆Σ ADC counterpart. For the same accuracy, the conversion cycle is shortened by a factor of more than 2⁹ compared to the IADC1. Fabricated in 0.18-μm CMOS process, the prototype ADC occupies 0.5 mm². With a 642 kHz clock, it achieves SNDR of 52.2 dB in the first step. The SNDR is boosted to 79.8 dB in the second step, and to 96.8 dB in the third step, over a 1 kHz signal band. The power consumption is 35 µW from a 1.5 V power supply. This gives an excellent Schreier FoM of 174.6 dB.
Secondly, a multi-step incremental ADC with extended binary counting is proposed. It achieves high accuracy by splitting one conversion cycle into two serial steps. During the first step, the ADC works as a first-order incremental ADC (IADC1). The second step reuses the single integrator and extends the accuracy to 16 bits by a two-capacitor SAR-assisted binary counting technique. For the same accuracy, the conversion cycle is shortened by a factor of more than 2⁸ as compared to the single-step IADC. Fabricated in 0.18-μm CMOS process, the SAR-assisted IADC achieves a peak SNR/SNDR/DR of 97.1/96.6/100.2 dB over a 1.2 kHz bandwidth, while dissipating 33.2 μW from a 1.5 V supply. This gives a Schreier FoM of 175.8 dB and Walden FoM of 0.25 pJ/conv.-step.
Finally, the design of a continuous-time ∆Σ modulator (CTDSM) to be used in an ultrasound beamformer for biomedical imaging is described. To achieve better resolution, the prototype modulator operates at 1.2 GHz. It incorporates a digital excess loop delay (ELD) compensation to replace the active adder in front of the internal quantizer. A digitally controlled reference-switching matrix, combined with the data-weighted averaging (DWA) technique, results in a delay-free feedback path. A multi-bit FIR feedback DAC, along with its compensation path, is used to achieve lower clock jitter sensitivity and better loop filter linearity. The modulator achieves 79.4 dB dynamic range, 77.3 dB SNR and 74.3 dB SNDR over a 15 MHz signal bandwidth. Fabricated in a 65 nm CMOS process, the core modulator occupies an area of only 0.16 mm² and dissipates 6.96 mW from a 1 V supply. A 58.6 fJ/conversion-step figure of merit was achieved.Keywords: Incremental ADC, multi-step operation, instrumentation and measurement, sensor interface, analog-to-digital converter, extended counting, chopper stabilization, delta-sigma ADC, multi-slope ADCsKeywords: Incremental ADC, multi-step operation, instrumentation and measurement, sensor interface, analog-to-digital converter, extended counting, chopper stabilization, delta-sigma ADC, multi-slope ADC
Robust sigma delta converters : and their application in low-power highly-digitized flexible receivers
In wireless communication industry, the convergence of stand-alone, single application transceiver IC’s into scalable, programmable and platform based transceiver ICs, has led to the possibility to create sophisticated mobile devices within a limited volume. These multi-standard (multi-mode), MIMO, SDR and cognitive radios, ask for more adaptability and flexibility on every abstraction level of the transceiver. The adaptability and flexibility of the receive paths require a digitized receiver architecture in which most of the adaptability and flexibility is shifted in the digital domain. This trend to ask for more adaptability and flexibility, but also more performance, higher efficiency and an increasing functionality per volume, has a major impact on the IP blocks such systems are built with. At the same time the increasing requirement for more digital processing in the same volume and for the same power has led to mainstream CMOS feature size scaling, leading to smaller, faster and more efficient transistors, optimized to increase processing efficiency per volume (smaller area, lower power consumption, faster digital processing). As wireless receivers is a comparably small market compared to digital processors, the receivers also have to be designed in a digitally optimized technology, as the processor and transceiver are on the same chip to reduce device volume. This asks for a generalized approach, which maps application requirements of complex systems (such as wireless receivers) on the advantages these digitally optimized technologies bring. First, the application trends are gathered in five quality indicators being: (algorithmic) accuracy, robustness, flexibility, efficiency, and emission, of which the last one is not further analyzed in this thesis. Secondly, using the quality indicators, it is identified that by introducing (or increasing) digitization at every abstraction level of a system, the advantages of modern digitally optimized technologies can be exploited. For a system on a chip, these abstraction levels are: system/application level, analog IP architecture level, circuit topology level and layout level. In this thesis, the quality indicators together with the digitization at different abstraction levels are applied to S¿ modulators. S¿ modulator performance properties are categorized into the proposed quality indicators. Next, it is identified what determines the accuracy, robustness, flexibility and efficiency of a S¿ modulator. Important modulator performance parameters, design parameter relations, and performance-cost relations are derived. Finally, several implementations are presented, which are designed using the found relations. At least one implementation example is shown for each level of digitization. At system level, a flexible (N)ZIF receiver architecture is digitized by shifting the ADC closer to the antenna, reducing the amount of analog signal conditioning required in front of the ADC, and shifting the re-configurability of such a receiver into the digital domain as much as possible. Being closer to the antenna, and because of the increased receiver flexibility, a high performance, multi-mode ADC is required. In this thesis, it is proven that such multi-mode ADCs can be made at low area and power consumption. At analog IP architecture level, a smarter S¿ modulator architecture is found, which combines the advantages of 1-bit and multi-bit modulators. The analog loop filter is partly digitized, and analog circuit blocks are replaced by a digital filter, leading to an area and power efficient design, which above all is very portable, and has the potential to become a good candidate for the ADC in multimode receivers. At circuit and layout level, analog circuits are designed in the same way as digital circuits are. Analog IP blocks are split up in analog unit cells, which are put in a library. For each analog unit cell, a p-cell layout view is created. Once such a library is available, different IP blocks can be created using the same unit cells and using the automatic routing tools normally used for digital circuits. The library of unit cells can be ported to a next technology very quickly, as the unit cells are very simple circuits, increasing portability of IP blocks made with these unit cells. In this thesis, several modulators are presented that are designed using this digital design methodology. A high clock frequency in the giga-hertz range is used to test technology speed. The presented modulators have a small area and low power consumption. A modulator is ported from a 65nm to a 45nm technology in one month without making changes to the unit cells, or IP architecture, proving that this design methodology leads to very portable designs. The generalized system property categorization in quality indicators, and the digitization at different levels of system design, is named the digital design methodology. In this thesis this methodology is successfully applied to S¿ modulators, leading to high quality, mixed-signal S¿ modulator IP, which is more accurate, more robust, more flexible and/or more efficient
Robust sigma delta converters : and their application in low-power highly-digitized flexible receivers
In wireless communication industry, the convergence of stand-alone, single application transceiver IC’s into scalable, programmable and platform based transceiver ICs, has led to the possibility to create sophisticated mobile devices within a limited volume. These multi-standard (multi-mode), MIMO, SDR and cognitive radios, ask for more adaptability and flexibility on every abstraction level of the transceiver. The adaptability and flexibility of the receive paths require a digitized receiver architecture in which most of the adaptability and flexibility is shifted in the digital domain. This trend to ask for more adaptability and flexibility, but also more performance, higher efficiency and an increasing functionality per volume, has a major impact on the IP blocks such systems are built with. At the same time the increasing requirement for more digital processing in the same volume and for the same power has led to mainstream CMOS feature size scaling, leading to smaller, faster and more efficient transistors, optimized to increase processing efficiency per volume (smaller area, lower power consumption, faster digital processing). As wireless receivers is a comparably small market compared to digital processors, the receivers also have to be designed in a digitally optimized technology, as the processor and transceiver are on the same chip to reduce device volume. This asks for a generalized approach, which maps application requirements of complex systems (such as wireless receivers) on the advantages these digitally optimized technologies bring. First, the application trends are gathered in five quality indicators being: (algorithmic) accuracy, robustness, flexibility, efficiency, and emission, of which the last one is not further analyzed in this thesis. Secondly, using the quality indicators, it is identified that by introducing (or increasing) digitization at every abstraction level of a system, the advantages of modern digitally optimized technologies can be exploited. For a system on a chip, these abstraction levels are: system/application level, analog IP architecture level, circuit topology level and layout level. In this thesis, the quality indicators together with the digitization at different abstraction levels are applied to S¿ modulators. S¿ modulator performance properties are categorized into the proposed quality indicators. Next, it is identified what determines the accuracy, robustness, flexibility and efficiency of a S¿ modulator. Important modulator performance parameters, design parameter relations, and performance-cost relations are derived. Finally, several implementations are presented, which are designed using the found relations. At least one implementation example is shown for each level of digitization. At system level, a flexible (N)ZIF receiver architecture is digitized by shifting the ADC closer to the antenna, reducing the amount of analog signal conditioning required in front of the ADC, and shifting the re-configurability of such a receiver into the digital domain as much as possible. Being closer to the antenna, and because of the increased receiver flexibility, a high performance, multi-mode ADC is required. In this thesis, it is proven that such multi-mode ADCs can be made at low area and power consumption. At analog IP architecture level, a smarter S¿ modulator architecture is found, which combines the advantages of 1-bit and multi-bit modulators. The analog loop filter is partly digitized, and analog circuit blocks are replaced by a digital filter, leading to an area and power efficient design, which above all is very portable, and has the potential to become a good candidate for the ADC in multimode receivers. At circuit and layout level, analog circuits are designed in the same way as digital circuits are. Analog IP blocks are split up in analog unit cells, which are put in a library. For each analog unit cell, a p-cell layout view is created. Once such a library is available, different IP blocks can be created using the same unit cells and using the automatic routing tools normally used for digital circuits. The library of unit cells can be ported to a next technology very quickly, as the unit cells are very simple circuits, increasing portability of IP blocks made with these unit cells. In this thesis, several modulators are presented that are designed using this digital design methodology. A high clock frequency in the giga-hertz range is used to test technology speed. The presented modulators have a small area and low power consumption. A modulator is ported from a 65nm to a 45nm technology in one month without making changes to the unit cells, or IP architecture, proving that this design methodology leads to very portable designs. The generalized system property categorization in quality indicators, and the digitization at different levels of system design, is named the digital design methodology. In this thesis this methodology is successfully applied to S¿ modulators, leading to high quality, mixed-signal S¿ modulator IP, which is more accurate, more robust, more flexible and/or more efficient