Design and Measurement of StrongARM Comparators

Whitehead, Nathan Robert

29 October 2019

The StrongARM comparator is utilized in many analog-to-digital converters (ADCs) because of its high power efficiency and rail-to-rail outputs. The performance of the comparator directly affects the speed, power, and accuracy of an ADC. However, the StrongARM comparator performance parameters such as delay, noise, and offset measured directly from silicon prototypes are rare in literature and often consist of small sample sets. In addition, existing techniques to measure the comparator require large chip areas, making it impractical to characterize a large number of comparators to obtain stochastic parameters such as offset and noise. This work presents novel circuit techniques to measure a large number of comparators (4,000) in a compact chip area to directly obtain silicon data including delay, noise, offset, and power. The proposed techniques also relax the requirement on the test instruments to measure the small time values. Four comparators with different transistor size ratios have been designed and measured to study the performance tradeoffs. In addition, this work presents a method utilizing supercomputing resources to simulate the large design space of the StrongARM comparator to observe the performance trends. Measurements are compared to simulations showing their accuracy and, for the first time, detailed study on the performance trends with different transistor size ratios.

StrongARM

comparator

latch

input-referred noise

delay

energy

supercomputer cadence simulations

Engineering

Embedded Computer for Space Applications suitable for Linux / Linuxanpassad inbyggnadsdator för rymdbruk

Dahlberg, Johan

January 2003

<p>This report briefly describes the special requirements for a computer board for use in space. In particular, component selection and ways of mitigating the soft and hard errors are discussed. Furthermore, one implementation for a low-cost, relatively high performance computer that will work in the harsh space environment is presented. The report is primarily intended for those familiar with digital design, who need an introduction to construction of space or other high-reliability hardware. </p><p>As the quality (resolution) of imagers, spectrometers and other data sources in scientific satellite payloads is increasing, there is also an increasing demand for more processing power in order to compress or in other way process the data before transmitting it on the limited bandwidth microwave downlink to Earth. Scientific instruments are usually mission specific and have rather low budget, so there is a need for a powerful computer board that can be used for a number of missions in order to keep the engineering costs down.</p>

Datorteknik

Embedded computer

Space

Linux

Radiation

Single event upsets

Error correction

Hamming codes

Microprocessor

Memory

StrongARM

FPGA

Datorteknik

Computer engineering

Datorteknik

Embedded Computer for Space Applications suitable for Linux / Linuxanpassad inbyggnadsdator för rymdbruk

Dahlberg, Johan

January 2003

This report briefly describes the special requirements for a computer board for use in space. In particular, component selection and ways of mitigating the soft and hard errors are discussed. Furthermore, one implementation for a low-cost, relatively high performance computer that will work in the harsh space environment is presented. The report is primarily intended for those familiar with digital design, who need an introduction to construction of space or other high-reliability hardware. As the quality (resolution) of imagers, spectrometers and other data sources in scientific satellite payloads is increasing, there is also an increasing demand for more processing power in order to compress or in other way process the data before transmitting it on the limited bandwidth microwave downlink to Earth. Scientific instruments are usually mission specific and have rather low budget, so there is a need for a powerful computer board that can be used for a number of missions in order to keep the engineering costs down.

Datorteknik

Embedded computer

Space

Linux

Radiation

Single event upsets

Error correction

Hamming codes

Microprocessor

Memory

StrongARM

FPGA

Datorteknik

Computer Engineering

Datorteknik

Design of Comparator with Offset Calibration for High-Speed ADCs

Baby, Basil

January 2024

High-speed ADC is essential in radio network systems for communications. However, accuracy is an important feature for them, their precision can be affected by minor discrepancies, e.g., offset voltage of comparators, which is a primary contributor to these discrepancies. This master thesis focuses on evaluating offset calibration techniques used for high-speed comparators. To start, a literature review is performed to learn about high-speed comparators and various offset calibration techniques, which helps to understand existing problems and new ideas in offset calibration. As the next step, evaluation and implementation of the reviewed literatures are done, which involves the implementation of schematics at the transistor level, where the calibration procedure's controller is implemented in Verilog-A. Finally, an extensive set of simulations, i.e., done by the electronic design automation tool, is conducted on the designed offset calibration techniques and how they affect the general operation of high-speed ADCs.  Among the reviewed calibration techniques, two discrete adjustment methods (trans-conductance and capacitive DAC) and three voltage-controlled methods (unbalanced clocks, second differential pair, and body bias) are implemented and evaluated. The discrete methods use digital circuits, which have large variations in step sizes due to mismatches, leading to higher offsets after calibration. Monte Carlo simulations are done to show this drawback clearly better. However, using thermometer code instead of the binary-weighted would help by making the step sizes more consistent, which yields better-offset calibration results. On the other hand, the voltage-controlled methods rely on external voltages, which require more design work because of the Digital-to-Analog Converter (DAC) units. During a calibration test with various input offsets, the 'Body Bias' technique exhibited the highest precision by achieving the smallest remaining offset.

comparator

offset

calibration

offset calibration

Calibration using unbalanced clocks

With second differential pair

With body bias

StrongARM

Elektroteknik och elektronik