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A 8-bit 20-MS/s Pipeline ADC and A Low-Power 5-bit 2.4-MS/s Successive Approximation ADC for ZigBee ReceiversCheng, Kuang-Ting 07 July 2006 (has links)
The first topic of this thesis proposes an 8-bit, 20 MSample/s pipeline analog-to-digital converter (ADC). The sharing amplifiers technique is employed to reduce the overall number of the amplifiers wherein dynamic comparators are adopted to reduce the power consumption. The proposed design is implemented by 0.35 £gm CMOS technology. The simulation results show that maximum power consumption is 45 mW given a 3.3 V power supply, and the SFDR is 45 dB with a sinusoidal input at 5 MHz.
The second topic is to describe a 5-bit, 2.4 MSample/s, low power analog-to-digital converter for ZigBee receiver using 868/915 MHz band. The converter uses the successive approximation architecture. By using 0.18 £gm CMOS technology, the simulation results show the worst-case power consumption is merely 449.6 £gW. The converter achieves the maximum differential nonlinearity of 0.3 LSB, the maximum integral nonlinearity of 0.5 LSB.
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A 12-bit, 10 Msps two stage SAR-based pipeline ADCGandara, Miguel Francisco 23 April 2013 (has links)
The market for battery powered communications devices has grown significantly in recent years. These devices require a large number of analog to digital converters (ADCs) to transform wireless and other physical data into the digital signals required for digital signal processing elements and micro-processors. For these applications, power efficiency and accuracy are of the
utmost importance. Successive approximation register (SAR) ADCs are frequently used in power constrained applications, but their main limitation is their low sampling rate. In this work, a two stage pipelined ADC is presented
that attempts to mitigate some of the sampling rate limitations of a SAR while maintaining its power and resolution advantages. Special techniques are used to reduce the overall sampling capacitance required in both SAR stages and
to increase the linearity of the multiplying digital to analog converter (MDAC) output. The SAR sampling network, control logic, and MDAC blocks are completely
implemented. Ideal components were used for the clocking, comparators, and switches. At the end of this design, a figure of merit of 51 fJ/conversion-step was achieved. / text
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Applying the "Split-ADC" Architecture to a 16 bit, 1 MS/s differential Successive Approximation Analog-to-Digital ConverterChan, Ka Yan 30 April 2008 (has links)
Successive Approximation (SAR) analog-to-digital converters are used extensively in biomedical applications such as CAT scan due to the high resolution they offer. Capacitor mismatch in the SAR converter is a limiting factor for its accuracy and resolution. Without some form of calibration, a SAR converter can only achieve 10 bit accuracy. In industry, the CAL-DAC approach is a popular approach for calibrating the SAR ADC, but this approach requires significant test time. This thesis applies the“Split-ADC" architecture with a deterministic, digital, and background self-calibration algorithm to the SAR converter to minimize test time. In this approach, a single ADC is split into two independent halves. The two split ADCs convert the same input sample and produce two output codes. The ADC output is the average of these two output codes. The difference between these two codes is used as a calibration signal to estimate the errors of the calibration parameters in a modified Jacobi method. The estimates are used to update calibration parameters are updated in a negative feedback LMS procedure. The ADC is fully calibrated when the difference signal goes to zero on average. This thesis focuses on the specific implementation of the“Split-ADC" self-calibrating algorithm on a 16 bit, 1 MS/s differential SAR ADC. The ADC can be calibrated with 105 conversions. This represents an improvement of 3 orders of magnitude over existing statistically-based calibration algorithms. Simulation results show that the linearity of the calibrated ADC improves to within ±1 LSB.
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Investigation of 10-bit SAR ADC using flip-flip bypass circuitFontaine, Robert Alexander 15 April 2014 (has links)
The Successive Approximation Register (SAR) Analog to Digital Converter (ADC) is power efficient and operates at moderate resolution. However, the conversion speed is limited by settling time and control logic constraints. This report investigates a flip-flop bypass technique to reduce the required conversion time. A conventional design and flip-flop bypass design are simulated using a 0.18[micrometer] CMOS process. Background and design of the control logic, comparator, capacitive array, and switches for implementing the SAR ADCs is presented with the emphasis on optimizing for conversion speed. / text
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An Energy Efficient Asynchronous Time-Domain ComparatorGao, Yang 02 October 2013 (has links)
In energy-limited applications, such as wearable battery powered systems and implantable circuits for biological applications, ultra-low power analog-to-digital converters (ADCs) are essential for sustaining long time operation. As a fundamental building block of ADC, comparator should support a tightened power budget. Therefore, developing low-power design techniques for comparator is becoming more and more important.
As an alternative to the conventional voltage-mode comparator, this thesis proposed an energy efficient time-domain comparator, which uses digital circuits to process analog signals by representing them as timing information. The proposed time-domain comparator has three main features: comparing on both clock edges (rising/falling), asynchronous comparison and 2-bit/step comparison. With these features, power consumption of the comparator can be effectively reduced.
For verification, the proposed time-domain comparator is fabricated in IBM 0.18um CMOS technology in comparison with other two conventional time-domain comparators working at 100kS/s sampling rate and 8-bit resolution. The achieved power consumption of the proposed time-domain comparator is 50nW, which is much lower than 84nW and 285nW of the other two time-domain comparators.
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Accelerating Successive Approximation Algorithm Via Action EliminationJaber, Nasser M. A. Jr. 20 January 2009 (has links)
This research is an effort to improve the performance of successive approximation algorithm with a prime aim of solving finite states and actions, infinite horizon, stationary, discrete and discounted
Markov Decision Processes (MDPs). Successive approximation is a simple and commonly used method to solve MDPs. Successive approximation often appears to be intractable for solving large scale MDPs due to its computational complexity. Action elimination, one of the techniques used to accelerate solving MDPs, reduces the
problem size through identifying and eliminating sub-optimal actions. In some cases successive approximation is terminated when all actions but one per state are eliminated.
The bounds on value functions are the key element in action elimination. New terms (action gain, action relative gain and action
cumulative relative gain) were introduced to construct tighter bounds on the value functions and to propose an improved action
elimination algorithm.
When span semi-norm is used, we show numerically that the actual convergence of successive approximation is faster than the known theoretical rate. The absence of easy-to-compute bounds on the actual convergence rate motivated the current research to try a
heuristic action elimination algorithm. The heuristic utilizes an estimated convergence rate in the span semi-norm to speed up action
elimination. The algorithm demonstrated exceptional performance in terms of solution optimality and savings in computational time.
Certain types of structured Markov processes are known to have monotone optimal policy. Two special action elimination algorithms
are proposed in this research to accelerate successive approximation for these types of MDPs. The first algorithm uses the state space partitioning and prioritize iterate values updating in a way that maximizes temporary elimination of sub-optimal actions based on the policy monotonicity. The second algorithm is an improved version that includes permanent action elimination to improve the performance of the algorithm. The performance of the proposed algorithms are assessed and compared to that of other algorithms. The proposed algorithms demonstrated outstanding performance in
terms of number of iterations and omputational time to converge.
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Accelerating Successive Approximation Algorithm Via Action EliminationJaber, Nasser M. A. Jr. 20 January 2009 (has links)
This research is an effort to improve the performance of successive approximation algorithm with a prime aim of solving finite states and actions, infinite horizon, stationary, discrete and discounted
Markov Decision Processes (MDPs). Successive approximation is a simple and commonly used method to solve MDPs. Successive approximation often appears to be intractable for solving large scale MDPs due to its computational complexity. Action elimination, one of the techniques used to accelerate solving MDPs, reduces the
problem size through identifying and eliminating sub-optimal actions. In some cases successive approximation is terminated when all actions but one per state are eliminated.
The bounds on value functions are the key element in action elimination. New terms (action gain, action relative gain and action
cumulative relative gain) were introduced to construct tighter bounds on the value functions and to propose an improved action
elimination algorithm.
When span semi-norm is used, we show numerically that the actual convergence of successive approximation is faster than the known theoretical rate. The absence of easy-to-compute bounds on the actual convergence rate motivated the current research to try a
heuristic action elimination algorithm. The heuristic utilizes an estimated convergence rate in the span semi-norm to speed up action
elimination. The algorithm demonstrated exceptional performance in terms of solution optimality and savings in computational time.
Certain types of structured Markov processes are known to have monotone optimal policy. Two special action elimination algorithms
are proposed in this research to accelerate successive approximation for these types of MDPs. The first algorithm uses the state space partitioning and prioritize iterate values updating in a way that maximizes temporary elimination of sub-optimal actions based on the policy monotonicity. The second algorithm is an improved version that includes permanent action elimination to improve the performance of the algorithm. The performance of the proposed algorithms are assessed and compared to that of other algorithms. The proposed algorithms demonstrated outstanding performance in
terms of number of iterations and omputational time to converge.
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LOW-POWER TECHNIQUES FOR SUCCESSIVE APPROXIMATION REGISTER (SAR) ANALOG-TO-DIGITAL CONVERTERSSekar, Ramgopal 01 August 2010 (has links)
In this work, we investigate circuit techniques to reduce the power consumption of Successive Approximation Register Analog-to-Digital Converter (SAR-ADC). We developed four low-power SAR-ADC design techniques, which are: 1) Low-power SAR-ADC design with split voltage reference, 2) Charge recycling techniques for low-power SAR-ADC design, 3) Low-power SAR-ADC design using two-capacitor arrays, 4) Power reduction techniques by dynamically minimizing SAR-ADC conversion cycles. Matlab simulations are performed to investigate the power saving by the proposed techniques. Simulation results show that significant power reduction can be achieved by using the developed techniques. In addition, design issues such as area overhead, design complexity associated with the proposed low-power techniques are also discussed in the thesis.
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Variable Precision Tandem Analog-to-Digital Converter (ADC)Parsons, Colton A 01 June 2014 (has links)
This paper describes an analog-to-digital signal converter which varies its precision as a function of input slew rate (maximum signal rate of change), in order to best follow the input in real time. It uses Flash and Successive Approximation (SAR) conversion techniques in sequence.
As part of the design, the concept of "total real-time optimization" is explored, where any delay at all is treated as an error (Error = Delay * Signal Slew Rate). This error metric is proposed for use in digital control systems. The ADC uses a 4-bit Flash converter in tandem with SAR logic that has variable precision (0 to 11 bits). This allows the Tandem ADC to switch from a fast, imprecise converter to a slow, precise converter. The level of precision is determined by the input’s peak rate of change, optimized for minimum real-time error; a secondary goal is to react quickly to input transient spikes.
The implementation of the Tandem ADC is described, along with various issues which arise when designing such a converter and how they may be dealt with. These include Flash ADC inaccuracies, rounding issues, and system timing and synchronization.
Most of the design is described down to the level of logic gates and related building blocks (e.g. latches and flip-flops), and various logic optimizations are used in the design to reduce calculation delays. The design also avoids active analog circuitry whenever possible – it can be almost entirely implemented with CMOS logic and passive analog components.
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Low power SAR analog-to-digital converter for internet-of-things RF receivers / Conversor analógico-digital SAR de baixo consumo para receptores RF de internet-das-coisasDornelas, Helga Uchoa January 2018 (has links)
The "Internet of Things" (IoT) has been a topic of intensive research in industry, technological centers and academic community, being data communication one aspect of high relevance in this area. The exponential increase of devices with wireless capabilities as well as the number of users, alongside with the decreasing costs for implementation of broadband communications, created a suitable environment for IoT applications. An IoT device is typically composed by a wireless transceiver, a battery and/or energy harvesting unit, a power management unit, sensors and conditioning unit, a microprocessor and data storage unit. Energy supply is a limiting factor in many applications and the transceiver usually demands a significant amount of power. In this scenario the emerging wireless communication standard IEEE 802.11ah, in which this work focuses, was proposed as an option for low power sub-GHz radio communication. A typical architecture of modern radio receivers contains the analog radio-frequency (RF) front-end, which amplifies, demodulates and filters the input signal, and also analog-to-digital converters (ADC), that translate the analog signals to the digital domain. Additionally, the Successive-Approximation (SAR) ADC architecture has become popular recently due to its power efficiency, simplicity, and compatibility with scaled-down integrated CMOS technology. In this work, the RF receiver architecture and its specifications aiming low power consumption and IEEE 802.11ah standard complying are outlined, being the basis to the proposition of an 8-bit resolution and 10 MHz sampling rate ADC. A power efficient switching scheme for the charge redistribution SAR ADC architecture is explored in detail, along with the circuit-level design of the digital-to-analog converter (DAC). The transistor-level design of the two remaining ADC main blocks, sampling switch and comparator, are also explored. Electrical simulation of the physical layout, including parasitics, at a 130nm CMOS process resulted in a SINAD of 47:3 dB and 45:5 dB and at the receiver IF 3 MHz and at the Nyquist rate, respectively, consuming 21 W with a power supply of 1 V . The SAR ADC resulting Figure-of-Merit (FoM) corresponded to 11:1 fJ/conv-step at IF, and 13:7 fJ/conv-step at the Nyquist rate.
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