2.45 GHz ZigBee Receiver Frontend and Delta-Sigma ADC with Constant-gm Amplifier for Battery Management Systems

Luo, Wayne

07 July 2012

This thesis consists of two topics: A 2.45 GHz ZigBee Receiver Frontend design for home energy-saving systems and a Delta-Sigma ADC with constant-gm amplifier for Battery Management Systems (BMS). A 2.45 GHz ZigBee Receiver Frontend for home energy-saving systems is pre-sented in the first part of this thesis. The proposed ZigBee receiver can be used in areas where wireline solutions are hard to be realized. By employing an LNA at the very frontend of the receiver, the gain is simulated to be 17.376 dB at 2.45 GHz. Besides, by using the double-balanced Gilbert mixer with a current bleeding MOS transistor, the NF and the IIP3 of the mixer are only 5.074 dB and -7.234 dB, respectively. To reduce the phase noise of the receiver, a fractional-N frequency synthesizer with a complementary cross-coupled VCO is adopted. The phase noise of the fractional-N frequency synthe-sizer is 137.7 dBc/Hz. The proposed circuit is carried out and measured on silicon using the standard TSMC 0.18 £gm CMOS process. In the second topic, a Delta-Sigma ADC with constant-gm amplifier is presented. The proposed ADC is particularly designed for the voltage detection circuit in BMS. A constant-gm amplifier is also presented to resolve the nonlinearity of the amplifier de-grading the performance of Delta-Sigma modulator, which is the frontend of the Del-ta-Sigma ADC. With the 4 KHz signal bandwidth, 512 KHz sampling frequency, and 128 oversampling rate, it shows a 85.2 dB SNR, and 12-bit resolution. The backend of the ADC is the decimator, which reduces the sampling frequency compliant with the Nyquist rate rule. The decimator is realized by Verilog code and verified by FPGA. By following the mixed-signal flow, the ADC is realized on a single chip using the standard TSMC 0.25 £gm 60V HV CMOS process.

BMS

ZigBee

receiver

Delta-Sigma ADC

constant-gm amplifier

Applications of Two-Point Delta-Sigma Modulation to FHSS Transmitters

Pan, Chi-Nan

09 July 2003

In the first, a time-variant modulus phase lock loop(PLL) model is established. Applying the model, Theorems of fractional-N synthesizers are introduced. We also explain theorems and simulations of Closed-Loop Modulation and Two-Point Delta Sigma Modulation with the model. In the end, a 2.4GHz FHSS transmitter using Two-Point Delta Sigma Modulation which meets Bluetooth specifications is demonstrated.

Delta-Sigma Modulator

Two-Point Modulation

Fractional-N Synthesizer

Study on a second-order bandpass Σ∆-modulator for flexible AD-conversion

Svensson, Hanna

January 2008

<p>An important component in many communication system is the digital to analog converter. The component is needed in order to convert real world analog quantities to digital quantities which are easier to process. As the market for hand held devices with wireless communication with the outer world has increased new approaches for sharing the frequency spectrum are needed. Therefore it would be interesting to look at the possibility to design an analog to digital converter that, in runtime, can change the frequency band converted, and hence the used standard. This thesis study one of the possibilities to design such an ADC, as a Σ∆ modulator, and more precise the structure called Cascade of resonators with distributed feedback and input (CRFB). The order of the modulator in this study is two.</p>

Sigma-Delta

Delta-Sigma

bandpass modulators

flexible ADC

Electronics

Elektronik

VCO-based analog-to-digital conversion

Hamilton, Joseph Garrett

07 November 2013

This dissertation presents a novel [delta sigma] analog-to-digital converter architecture which replaces the operational amplifier-based integrator with a pair of tunable oscillators. A switched-capacitor V-I converter is used to combine the input voltage with a feedback DAC output and convert it into a current for two pseudo-differential current-controlled oscillators. The oscillator outputs are counted with a digital counter, and a digital back-end [delta sigma] modulator is used to truncate the high-resolution counter outputs for the feedback DAC path. This architecture has compelling advantages in deep sub-micron and emerging technologies where supply voltages are decreasing to a point that traditional analog architectures are no longer feasible. Additionally, this architecture takes advantage of the increased speed in these short-channel technologies. Measured results on a 6.08mW prototype in TSMC 0.18um achieving 63.5dB in a 2MHz bandwidth are presented. / text

VCO

Ring oscillator

Delta-sigma

ADC

Time-based

Integrated temperature sensors in deep sub-micron CMOS technologies

Chowdhury, Golam Rasul

03 July 2014

Integrated temperature sensors play an important role in enhancing the performance of on-chip power and thermal management systems in today's highly-integrated system-on-chip (SoC) platforms, such as microprocessors. Accurate on-chip temperature measurement is essential to maximize the performance and reliability of these SoCs. However, due to non-uniform power consumption by different functional blocks, microprocessors have fairly large thermal gradient (and variation) across their chips. In the case of multi-core microprocessors for example, there are task-specific thermal gradients across different cores on the same die. As a result, multiple temperature sensors are needed to measure the temperature profile at all relevant coordinates of the chip. Subsequently, the results of the temperature measurements are used to take corrective measures to enhance the performance, or save the SoC from catastrophic over-heating situations which can cause permanent damage. Furthermore, in a large multi-core microprocessor, it is also imperative to continuously monitor potential hot-spots that are prone to thermal runaway. The locations of such hot spots depend on the operations and instruction the processor carries out at a given time. Due to practical limitations, it is an overkill to place a big size temperature sensor nearest to all possible hot spots. Thus, an ideal on-chip temperature sensor should have minimal area so that it can be placed non-invasively across the chip without drastically changing the chip floor plan. In addition, the power consumption of the sensors should be very low to reduce the power budget overhead of thermal monitoring system, and to minimize measurement inaccuracies due to self-heating. The objective of this research is to design an ultra-small size and ultra-low power temperature sensor such that it can be placed in the intimate proximity of all possible hot spots across the chip. The general idea is to use the leakage current of a reverse-bias p-n junction diode as an operand for temperature sensing. The tasks within this project are to examine the theoretical aspect of such sensors in both Silicon-On-Insulator (SOI), and bulk Complementary Metal-Oxide Semiconductor (CMOS) technologies, implement them in deep sub-micron technologies, and ultimately evaluate their performances, and compare them to existing solutions. / text

CMOS

TDC

ADC

BJT

p-n

Delta-sigma

DVFS

SoC

Analog-to-digital converter circuit and system design to improve with CMOS scaling

Mortazavi, Yousof

08 September 2015

There is a need to rethink the design of analog/mixed-signal circuits to be viable in state-of-the-art nanometer-scale CMOS processes due to the hostile environment they create for analog circuits. Reduced supply voltages and smaller capacitances are beneficial to circuit speed and digital circuit power efficiency; however, these changes along with smaller dimensions and close coupling of fast-switching digital circuits have made high-accuracy voltage domain analog processing increasingly difficult. In this work, techniques to improve analog-to-digital converters (ADC) for nanometer-scale processes are explored. First, I propose a mostly-digital time-based oversampling delta-sigma (∆Σ) ADC architecture. This system uses time, rather than voltage, as the analog variable for its quantizer, where the noise shaping process is realized by modulating the width of a variable-width digital "pulse." The merits of this architecture render it not only viable to scaling, but also enable improved circuit performance with ever-increasing time resolution of scaled CMOS processes. This is in contrast to traditional voltage-based analog circuit design, whose performance generally decreases with scaling due to increasingly higher voltage uncertainty due to supply voltage reduction and short-channel effects. In conjunction with Dr. Woo Young Jung while he was a Ph.D. student at The University of Texas at Austin, two prototype implementations of the proposed architecture were designed and fabricated in TSMC 180 nm CMOS and IBM 45 nm Silicon-On-Insulator (SOI) processes. The prototype ADCs demonstrate that the architecture can achieve bandwidths of 5-20 MHz and ∼50 dB SNR with very small area. The first generation ADC core occupies an area of only 0.0275 mm² , while the second generation ADC core occupies 0.0192 mm² . The two prototypes can be categorized as some of the smallestarea modulators in the literature. Second, I analyze the measured results of the prototype ADC chips, and determine the source for the harmonic distortion. I then demonstrate a digital calibration algorithm that sufficiently mitigates the distortion. This calibration approach falls in the general philosophy of digitally-assisted analog systems. In this philosophy, digital calibration and post-correction are favored over traditional analog solutions, in which there is a high cost to the analog solution either in complexity, power, or area. / text

Analog-to-digital converters

Time-based ADCs

Delta-sigma modulators

Tunable mismatch shaping for bandpass Delta-Sigma data converters

Akram, Waqas

16 June 2011

Oversampled digital-to-analog converters typically employ an array of unit elements to drive out the analog signal. Manufacturing defects can create errors due to mismatch between the unit elements, leading to a sharp reduction in the effective dynamic range through the converter. Mismatch noise shaping is an established technique for alleviating these effects, but usually anchors the signal band to a fixed frequency location. In order to extend these advantages to tunable applications, this work explores a series of techniques that allow the suppression band of the mismatch noise shaping function to have an adjustable center frequency. The proposed techniques are implemented in hardware and evaluated according to mismatch shaping performance, latency and hardware complexity. / text

Mismatch shaping

ADC

DAC

Delta Sigma modulator

Vector shaper

Study on a second-order bandpass Σ∆-modulator for flexible AD-conversion

Svensson, Hanna

January 2008

An important component in many communication system is the digital to analog converter. The component is needed in order to convert real world analog quantities to digital quantities which are easier to process. As the market for hand held devices with wireless communication with the outer world has increased new approaches for sharing the frequency spectrum are needed. Therefore it would be interesting to look at the possibility to design an analog to digital converter that, in runtime, can change the frequency band converted, and hence the used standard. This thesis study one of the possibilities to design such an ADC, as a Σ∆ modulator, and more precise the structure called Cascade of resonators with distributed feedback and input (CRFB). The order of the modulator in this study is two.

Sigma-Delta

Delta-Sigma

bandpass modulators

flexible ADC

Electronics

Elektronik

Low-power Charge-pump Based Switched-capacitor Circuits

Nilchi, Alireza

09 August 2013

In this thesis, low-power charge-pump (CP) based switched-capacitor (SC) circuits are proposed. The approach is validated in SC integrators and gain stages, and is shown to achieve power savings compared to conventional SC circuits. For the same thermal noise and settling performance, a CP based integrator with N sampling capacitors ideally consumes N^2 times lower OTA power compared to a conventional integrator. Practical effects such as the OTA partial slew-rate limitation and the CP parasitics reduce the power savings. In the case of a SC gain stage, reduction in power savings also occurs due to the load capacitance from the next stage. A prototype delta-sigma modulator employing a CP integrator at the front-end is fabricated. Experimental results demonstrate that the CP based ADC achieves the same performance as a conventional ADC while consuming three times lower OTA power in the front-end integrator. The CP ADC achieves 87.8 dB SNDR 89.2 dB SNR and 90 dB DR over a 10 kHz bandwidth while consuming 148 uW from a 1.2 V power supply. The conventional ADC has similar performance but dissipates 241 uW. The CP ADC figure-of-merit (FOM) is 0.369 pJ/conv-step, which is almost 40% lower than that of the conventional ADC.

Switched-Capacitor Circuits

Charge-Pump

Delta-Sigma Modulator

0544

Low-power Charge-pump Based Switched-capacitor Circuits

Nilchi, Alireza

09 August 2013

In this thesis, low-power charge-pump (CP) based switched-capacitor (SC) circuits are proposed. The approach is validated in SC integrators and gain stages, and is shown to achieve power savings compared to conventional SC circuits. For the same thermal noise and settling performance, a CP based integrator with N sampling capacitors ideally consumes N^2 times lower OTA power compared to a conventional integrator. Practical effects such as the OTA partial slew-rate limitation and the CP parasitics reduce the power savings. In the case of a SC gain stage, reduction in power savings also occurs due to the load capacitance from the next stage. A prototype delta-sigma modulator employing a CP integrator at the front-end is fabricated. Experimental results demonstrate that the CP based ADC achieves the same performance as a conventional ADC while consuming three times lower OTA power in the front-end integrator. The CP ADC achieves 87.8 dB SNDR 89.2 dB SNR and 90 dB DR over a 10 kHz bandwidth while consuming 148 uW from a 1.2 V power supply. The conventional ADC has similar performance but dissipates 241 uW. The CP ADC figure-of-merit (FOM) is 0.369 pJ/conv-step, which is almost 40% lower than that of the conventional ADC.

Switched-Capacitor Circuits

Charge-Pump

Delta-Sigma Modulator

0544