Kush Gulati scite author profile

A high-swing CMOS telescopic operational amplifier

Gulati

¹

,

Lee

²

1998

IEEE J. Solid-State Circuits

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A high-swing, high-performance CMOS telescopic operational amplifier is described. The high swing of the op-amp is achieved by employing the tail and current source transistors in the deep linear region. The resulting degradation in differential gain, common-mode rejection ratio (CMRR), and other amplifier characteristics are compensated by applying regulatedcascode differential gain enhancement and a replica-tail feedback technique. A prototype of the op-amp has been built in a 0.8m CMOS process. Operating from a power supply of 3.3 V, it achieves a differential swing of 62.45 V, a differential gain of 90 dB, unity-gain frequency of 90 MHz, and >50-dB CMRR. It is shown, analytically and through simulations, that the operational amplifier maintains its high CMRR even at high frequencies.

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A low-power reconfigurable analog-to-digital converter

Gulati¹,

Lee²

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This thesis presents the concept, theory and design of a low power CMOS analog-to-digital converter that can digitize signals over a wide range of bandwidth and resolution with adaptive power consumption. The converter achieves the wide operating range by reconfiguring (1) its architecture between pipeline and delta-sigma modes (2) by varying its circuit parameters such as size of capacitors, length of pipeline, oversampling ratio, among others and (3) by varying the bias currents of the opamps in proportion with converter sampling frequency, accomplished through the use of a phase-locked loop. Target input signals for this ADC include high frequency and moderate resolution signals such as video and low I.F. in radio Receivers, low frequency and high resolution signals from seismic sensors and MEMs devices, and others that fall in between these extremes such as audio, voice and general purpose data-acquisition. This converter also incorporates several power reducing features such as thermal noise limited design, global converter chopping in the pipeline mode, opamp scaling, opamp sharing between consecutive stages in the pipeline mode, an opamp chopping technique in the delta-sigma mode, and other design techniques. The opamp chopping technique achieves faster closed-loop settling time and lower thermal noise than conventional design.At a converter power supply at 3.3V, the converter achieves a bandwidth range of 0-10MHz over a resolution range of 6 -16 bits, and parameter reconfiguration time of 12 clock cycles. Its PLL lock range is measured at 20KHz to 40MHz. In the delta-sigma mode, it achieves a maximum SNR of 94dB and second and third harmonic distortions of 102dB and 95dB, respectively at 10MHz clock frequency, 9.4KHz bandwidth, and 17.6mW power. In the pipeline mode, it achieves a maximum DNL and INL of +/-0.55LSBs and +/-0. 82LSBs, respectively, at 11-bits of resolution, at a clock frequency of 2.6MHz and 1MHz tone with 24.6mW of power.

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A low-power reconfigurable analog-to-digital converter

Gulati

¹

,

Lee

²

2001

IEEE J. Solid-State Circuits

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This thesis presents the concept, theory and design of a low power CMOS analog-to-digital converter that can digitize signals over a wide range of bandwidth and resolution with adaptive power consumption. The converter achieves the wide operating range by reconfiguring (1) its architecture between pipeline and delta-sigma modes (2) by varying its circuit parameters such as size of capacitors, length of pipeline, oversampling ratio, among others and (3) by varying the bias currents of the opamps in proportion with converter sampling frequency, accomplished through the use of a phase-locked loop. Target input signals for this ADC include high frequency and moderate resolution signals such as video and low I.F. in radio Receivers, low frequency and high resolution signals from seismic sensors and MEMs devices, and others that fall in between these extremes such as audio, voice and general purpose data-acquisition. This converter also incorporates several power reducing features such as thermal noise limited design, global converter chopping in the pipeline mode, opamp scaling, opamp sharing between consecutive stages in the pipeline mode, an opamp chopping technique in the delta-sigma mode, and other design techniques. The opamp chopping technique achieves faster closed-loop settling time and lower thermal noise than conventional design.At a converter power supply at 3.3V, the converter achieves a bandwidth range of 0-10MHz over a resolution range of 6 -16 bits, and parameter reconfiguration time of 12 clock cycles. Its PLL lock range is measured at 20KHz to 40MHz. In the delta-sigma mode, it achieves a maximum SNR of 94dB and second and third harmonic distortions of 102dB and 95dB, respectively at 10MHz clock frequency, 9.4KHz bandwidth, and 17.6mW power. In the pipeline mode, it achieves a maximum DNL and INL of +/-0.55LSBs and +/-0. 82LSBs, respectively, at 11-bits of resolution, at a clock frequency of 2.6MHz and 1MHz tone with 24.6mW of power.

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