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1	A Low-Power 12bits 150-MS/s Pipelined Asynchronous Successive Approximation Analog-to-Digital Converter Yen, Yu-Wen 15 February 2011 (has links) In this thesis, the circuits are designing with TSMC.18£gm CMOS process and 1.8V of supply voltage. The speed and resolution of ADC are 150MS/s and 12-bits individually. In order to achieve a high speed, low power consumption pipelined ADC. The proposed pipelined stage is replaced Flash ADC by SAR ADC and add an extra comparator to determine one additional bit in sampling phase of pipelined stage. This technique reduces large number of pipelined stage and opamp which is energy-hungry in the pipelined ADC. Second, the SAR ADC provides inherent sample-and-hold mechanism so that the front-end sample-and-hold amplifier circuit is non-need. Third, the SAR ADC can achieve rail-to-rail input signal swing and improve the conversion accuracy rather than Flash ADC. The dynamic comparator is used for lower power consumption for whole circuit. Furthermore, this pipelined ADC implement under a supply voltage as low as 1.8V. The bootstrapped switch is used for controlling the sampling in the front-end. It can reduce the impacts of linearity for operating under low supply voltage. The operation amplifier implement by the partially switched-opamp technique to reduce more power consumption. Finally, the output codes are translated by digital correction circuit, it enhance the comparators input offset error tolerance. Switched-Opamp Pipelined ADC SAR ADC Bootstrapped switch Dynamic comparator
2	Vliv rozlišení MDAC na bloky řetězového převodníku AD / The influence of MDAC resolution on basic blocks of pipelined AD converter Kledrowetz, Vilém January 2009 (has links) This work deals with the influence of MDAC (multiplying DAC) resolution on basic blocks of pipelined AD converter. The MDAC was designed with 1,5 and 2,5 bits resolution structure using switched capacitor technique (SC) utilizing CMOS 0,7 m technology. Basic stages of this pipelined ADC are analyzed and compared.
3	Low-power 8-bit Pipelined ADC with current mode Multiplying Digital-to-Analog Converter (MDAC) Shahzad, Khurram January 2009 (has links) <p>In order to convert the analog information in the digital domain, pipelined analog-to-digital converter (ADC) offers an optimum balance of resolution, speed, power consumption, size and design effort.</p><p>In this thesis work we design and optimize a 8-bit pipelined ADC for low-power. The ADC has stage resolution of 1.5-bit and employ current mode multiplying analog-to-digital converter (MDAC). The main focus is to design and optimize the MDAC. Based on the analysis of "On current mode circuits" discussed in chapter 2, we design and optimize the MDAC circuit for the best possible effective number of bits (ENOB), speed and power consumption. Each of the first six stages consisting of Sample-and-Hold, 1.5-bit flash ADC and MDAC is realized at the circuit level. The last stage consisting of 2-bit flash ADC is also realized at circuit level. The delay logic for synchronization is implemented in Verilog-A and MATLAB. A first order digital error-correction algorithm is implemented in MATLAB.</p><p>The design is simulated in UMC 0.18um technology in Cadence environment. The choice of technology is made as the target application for the ADC, 'X-ray Detector System' is designed in the same technology. The simulation results obtained in-term of ENOB and power consumption are satisfactory for the target application.</p> ADC Pipelined ADC MDAC ENOB low-power digital error-correction Electronics Elektronik
4	Low-power 8-bit Pipelined ADC with current mode Multiplying Digital-to-Analog Converter (MDAC) Shahzad, Khurram January 2009 (has links) In order to convert the analog information in the digital domain, pipelined analog-to-digital converter (ADC) offers an optimum balance of resolution, speed, power consumption, size and design effort. In this thesis work we design and optimize a 8-bit pipelined ADC for low-power. The ADC has stage resolution of 1.5-bit and employ current mode multiplying analog-to-digital converter (MDAC). The main focus is to design and optimize the MDAC. Based on the analysis of "On current mode circuits" discussed in chapter 2, we design and optimize the MDAC circuit for the best possible effective number of bits (ENOB), speed and power consumption. Each of the first six stages consisting of Sample-and-Hold, 1.5-bit flash ADC and MDAC is realized at the circuit level. The last stage consisting of 2-bit flash ADC is also realized at circuit level. The delay logic for synchronization is implemented in Verilog-A and MATLAB. A first order digital error-correction algorithm is implemented in MATLAB. The design is simulated in UMC 0.18um technology in Cadence environment. The choice of technology is made as the target application for the ADC, 'X-ray Detector System' is designed in the same technology. The simulation results obtained in-term of ENOB and power consumption are satisfactory for the target application. ADC Pipelined ADC MDAC ENOB low-power digital error-correction Electronics Elektronik
5	A high-speed two-step analog-to-digital converter with an open-loop residue amplifier Dinc, Huseyin 04 April 2011 (has links) It is well known that feedback is a very valuable tool for analog designers to improve linearity, and desensitize various parameters affected by process, temperature and supply variations. However, using strong global feedback limits the operation speed of analog circuits due to stability requirements. The circuits and techniques explored in this research avoid the usage of strong-global-feedback circuits to achieve high conversion rates in a two-stage analog-to-digital converter (ADC). A two-step, 9-bit, complementary-metal-oxide-semiconductor (CMOS) ADC utilizing an open-loop residue-amplifier is demonstrated. A background-calibration technique was proposed to generate the reference voltage to be used in the second stage of the ADC. This technique alleviates the gain variation in the residue amplifier, and allows an open-loop residue amplifier topology. Even though the proposed calibration idea can be extended to multistage topologies, this design was limited to two stages. Further, the ADC exploits a high-performance double-switching frontend sample-and-hold amplifier (SHA). The proposed double-switching SHA architecture results in exceptional hold-mode isolation. Therefore, the SHA maintains the desired linearity performance over the entire Nyquist bandwidth. PGA Calibration SHA Switched-buffer Pipelined ADC Bipolar transistors Analog-to-digital converters Digital electronics
6	Energy Efficient Techniques For Algorithmic Analog-To-Digital Converters Hai, Noman January 2011 (has links) Analog-to-digital converters (ADCs) are key design blocks in state-of-art image, capacitive, and biomedical sensing applications. In these sensing applications, algorithmic ADCs are the preferred choice due to their high resolution and low area advantages. Algorithmic ADCs are based on the same operating principle as that of pipelined ADCs. Unlike pipelined ADCs where the residue is transferred to the next stage, an N-bit algorithmic ADC utilizes the same hardware N-times for each bit of resolution. Due to the cyclic nature of algorithmic ADCs, many of the low power techniques applicable to pipelined ADCs cannot be directly applied to algorithmic ADCs. Consequently, compared to those of pipelined ADCs, the traditional implementations of algorithmic ADCs are power inefficient. This thesis presents two novel energy efficient techniques for algorithmic ADCs. The first technique modifies the capacitors' arrangement of a conventional flip-around configuration and amplifier sharing technique, resulting in a low power and low area design solution. The other technique is based on the unit multiplying-digital-to-analog-converter approach. The proposed approach exploits the power saving advantages of capacitor-shared technique and capacitor-scaled technique. It is shown that, compared to conventional techniques, the proposed techniques reduce the power consumption of algorithmic ADCs by more than 85\%. To verify the effectiveness of such approaches, two prototype chips, a 10-bit 5 MS/s and a 12-bit 10 MS/s ADCs, are implemented in a 130-nm CMOS process. Detailed design considerations are discussed as well as the simulation and measurement results. According to the simulation results, both designs achieve figures-of-merit of approximately 60 fJ/step, making them some of the most power efficient ADCs to date. Analog-to-digital Converters Algorithmic ADC Pipelined ADC Capacitor Sharing Technique Capacitor Scaling Technique low power CMOS Energy efficient Electrical and Computer Engineering
7	Energy Efficient Techniques For Algorithmic Analog-To-Digital Converters Hai, Noman January 2011 (has links) Analog-to-digital converters (ADCs) are key design blocks in state-of-art image, capacitive, and biomedical sensing applications. In these sensing applications, algorithmic ADCs are the preferred choice due to their high resolution and low area advantages. Algorithmic ADCs are based on the same operating principle as that of pipelined ADCs. Unlike pipelined ADCs where the residue is transferred to the next stage, an N-bit algorithmic ADC utilizes the same hardware N-times for each bit of resolution. Due to the cyclic nature of algorithmic ADCs, many of the low power techniques applicable to pipelined ADCs cannot be directly applied to algorithmic ADCs. Consequently, compared to those of pipelined ADCs, the traditional implementations of algorithmic ADCs are power inefficient. This thesis presents two novel energy efficient techniques for algorithmic ADCs. The first technique modifies the capacitors' arrangement of a conventional flip-around configuration and amplifier sharing technique, resulting in a low power and low area design solution. The other technique is based on the unit multiplying-digital-to-analog-converter approach. The proposed approach exploits the power saving advantages of capacitor-shared technique and capacitor-scaled technique. It is shown that, compared to conventional techniques, the proposed techniques reduce the power consumption of algorithmic ADCs by more than 85\%. To verify the effectiveness of such approaches, two prototype chips, a 10-bit 5 MS/s and a 12-bit 10 MS/s ADCs, are implemented in a 130-nm CMOS process. Detailed design considerations are discussed as well as the simulation and measurement results. According to the simulation results, both designs achieve figures-of-merit of approximately 60 fJ/step, making them some of the most power efficient ADCs to date. Analog-to-digital Converters Algorithmic ADC Pipelined ADC Capacitor Sharing Technique Capacitor Scaling Technique low power CMOS Energy efficient Electrical and Computer Engineering
8	Návrh převodníku AD s nízkým napájecím napětím v technologii CMOS / Design of AD converter with low supply voltage in CMOS technology Holas, Jiří January 2016 (has links) Tato diplomová práce se zabývá návrhem 12 bitového řetězového A/D převodníku. Součástí návrhu bylo vytvořit referenční model převodníku v prostředí Matlab a determinovat faktory, které negativně ovlivňují výsledek konverze. S využitím nabytých poznatků navrhnout řetězový převodník na transistorové úrovni v prostředí Cadence. V teoretické části jsou shrnuty základy A/D převodu a dále jsou představeny nejčastěji používané architektury A/D převodníků. V dalších částech je popsán a diskutován vliv neidealit na vlastnosti řetězových převodníků. Praktická část se již věnuje popisu základních charakteristik řetězových převodníků a dokazuje funkci modelu. Z výsledků modelové struktury byly stanoveny reálné parametry, které byly dále využity v procesu tvorby návrhu v CMOS technologii TSMC 0,18m s nízkým napájecím napětím.

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