A technique to reduce the capacitor size in two stage Miller compensated opamp

In this paper two stage Miller compensated opamp has been discussed qualitatively and quantitatively. A modification to the conventional compensation network has been proposed, which will reduce the capacitor size hence circuit area. Transfer function for the newly proposed solution has been derived and explained the results. A prototype was developed in 65nm TSMC CMOS technology and simulation results have been presented. Amplifier achieved 60dB low frequency gain, 12MHz bandwidth and 55° phase margin while consuming 650uW power from 1.2V power supply. Circuit occupies 5348um 2 silicon area

Tehonhallinta integroidulle hermosignaalin hallintapiirille

Wireless biosignal measurement is a growing opportunity to increase the efficiency of medical procedures: An integrated circuit (receiver) is implanted inside human tissue and it’s output can be read wirelessly with a transmitter that also provides energy for the implant. This method requires RFID technology, where wireless data is transmitted in the RF-band back-and-forth between the receiver and transmitter. The receiver can be implemented either as an active design, where a local power supply is required inside the receiver, or as a passive design without internal energy storage. However, as the modern CMOS process is fairly advanced and the power consumption is low - passive designs are the most common. In the passive design the power for the receiver is drawn from the electromagnetic field transmitted to the chip, generally with electromagnetic induction. A design and implementation of an 860 MHz UHF-band RFID power system is presented in this work and its performance evaluated. The system was designed for a wireless EEG (electroencephalography) reader that can be implanted under the skalp – but the design principles can be expanded upon any RF-band RFID system. The final system works with an input power of -6.8 dBm with a startup time of slightly below 40 µs with specifications of 700 mV to 150 µA load. The LDO line regulation achieves a -51 dB level at DC with the full bandwidth covered. The RF Rectifier uses the design principles of a cross-coupled rectifier and a 63% conversion efficiency is achieved with the proposed matching circuitry. The reference circuitry is designed with the Betamultiplier architecture and expanded slightly to improve the current consumption in the circuit. The reference current is set at 100 nA and reference voltage at 400 mV.Langaton biosignaalien mittaus mahdollistaa yleisien lääketieteellisien signaalien mittauksien tehokkuuden kasvamista: Integroitu elektroninen piiri voidaan asentaa ihmisen kudokseen ja tämän sirun ulosantama tieto voidaan lukea langattomasti lukijalla, mikä useassa tapauksessa toimittaa myös energian sirulle. Tämä teknologia vaatii RFID teknologiaa, mikä on hyvin tunnettu ja tutkittu langattoman datan siirtämiseen kehitelty teknologia radiotaajuuksilla lukijan ja vastaanottimen välillä. Lukija voidaan suunnitella sekä passiiviseksi että aktiiviseksi, mutta modernin CMOS- teknologian tehonkulutus ominaisuuksien vuoksi RFID-lukijat ovat yleisesti passiivisia. Passiivisessa RFID suunnittelussa lukija vastaanottaa tarvitsemansa energian vastaanottimelta yleisesti elektromagneettisen induktion avulla. 860 MHz UHF-kaistan suunnitelu ja toteutus käydään läpi tässä työssä ja suorityskyky on mitattu simulaatioilla. Itse järjestelmä oli alunperin suunniteltu langattomaan EEG-lukijaan (aivosähkökäyrä), minkä pystyisi asentamaan päänahan alle - mutta periaatteet pätevät mihin tahansa RF-kaistan järjestelmään. Lopullinen järjestelmä toimii -6.8 dBm sisääntuloteholla ja käynnistysmisaika on hieman alle 40µs 700 mV ja 150 µA kuormaan. Linjaregulaatio saavuttaa -51 dB arvon alhaisilla taajuuksilla ja regulaatio on koko kaistan kattava. RF-tasasuuntaaja saavuttaa 63 % AC-DC huippu tehonmuutosarvon ehdotetulla impedanssien sovituspiirillä. Referenssipiiri on suunnitellu Betamultiplier-arkkitehtuurilla ja modifioitu pienentämään virrankulutusta. Referenssit ovat 100 nA ja 400 mV

Low-voltage Low-power Bulk-driven CMOS Op-Amp Using Negative Miller Compensation for ECG

Two bulk-driven CMOS (Complementary Metal Oxide Semiconductor) operational amplifier (op-amp) designs for electrocardiogram (ECG) application are presented and compared in this paper. Both op-amps are based on two-stage amplification, where bulk-driven differential input is the first stage, while additional DC gain is the second stage. Different compensation techniques were integrated in each op-amp design. Standard Miller compensation was used for the first op-amp parallel with the second stage. The novelty of the second op-amp is that it utilizes negative Miller compensation between the bulk-driven input node and the output node of the first stag, while standard Miller compensation was used in the second stage. The purpose of this work was to compare DC gain, phase margin (PM) and unit gain frequency (UGF) obtained through different simulated compensation strategies and test results. The op-amps were simulated using 0.25 μm CMOS technology. The simulation results are presented using the standard model libraries from Tanner EDA tools, operating on a single rail +0.8V power supply

Analog multiply and accumulate FPA readout circuit with digital multiply and sign maintenance

The high bandwidth and power needed to process the data coming from modern high resolution focal plane arrays leads to the necessity for fast and efficient read out and data processing. A system that performs block recognition and image classification with efficiency and low latency is presented. The system is comprised of an analog signal processor that will be integrated into the read out integrated circuit. This enables the capability to read out the focal plane array information and process it completely in the analog domain in a comparably very small amount of operational steps. The steps and techniques of the design flow, including definition of problem, concepts and design of system architecture, simulation of system, and analog lay out practices are covered

Low-voltage Low-power Bulk-driven CMOS Op-Amp Using Negative Miller Compensation for ECG

Two bulk-driven CMOS (Complementary Metal Oxide Semiconductor) operational amplifier (op-amp) designs for electrocardiogram (ECG) application are presented and compared in this paper. Both op-amps are based on two-stage amplification, where bulk-driven differential input is the first stage, while additional DC gain is the second stage. Different compensation techniques were integrated in each op-amp design. Standard Miller compensation was used for the first op-amp parallel with the second stage. The novelty of the second op-amp is that it utilizes negative Miller compensation between the bulk-driven input node and the output node of the first stag, while standard Miller compensation was used in the second stage. The purpose of this work was to compare DC gain, phase margin (PM) and unit gain frequency (UGF) obtained through different simulated compensation strategies and test results. The op-amps were simulated using 0.25 μm CMOS technology. The simulation results are presented using the standard model libraries from Tanner EDA tools, operating on a single rail +0.8V power supply

A PVT tolerant voltage-controlled oscillator for automotive applications

This thesis focusses on the development of an integrated oscillator for automotive applications. The oscillator operates based on the Barkhausen criterion, which is a mathematical requirement used in electronics to predict whether a linear electronic circuit will oscillate. In this thesis, a voltage-controlled oscillator is designed for increased performance under various process, voltage and temperature (PVT) conditions. By applying a voltage reference block, the output frequency of 0.5MHz, 0.75MHz, 1MHz or 1.25MHz can be obtained. In order to compensate for the variations at PVT corners, the trimming technology is applied to increase the accuracy. The supply voltage is considered to be varying between 2.1V and 5.5V while the temperature range is -40oC -125oC.Includes bibliographical references

A Low-Power Sigma-Delta Modulator for Healthcare and Medical Diagnostic Applications

This paper presents a switched-capacitor Sigma-Delta modulator designed in 90-nm CMOS technology, operating at 1.2-V supply voltage. The modulator targets healthcare and medical diagnostic applications where the readout of small-bandwidth signals is required. The design of the proposed A/D converter was optimized to achieve the minimum power consumption and area. A remarkable performance improvement is obtained through the integration of a low-noise amplifier with modified Miller compensation and rail-to-rail output stage. The manuscript also presents a set of design equations, from the small-signal analysis of the amplifier, for an easy design of the modulator in different technology nodes. The Sigma-Delta converter achieves a measured 96-dB dynamic range, over a 250-Hz signal bandwidth, with an oversampling ratio of 500. The power consumption is 30 μW, with a silicon area of 0.39 mm²