Your search keyword '"Bakkaloglu, Bertan"' showing total 4 results

1. Low-Power/Low-Voltage Integrated CMOS Sense Resistor-Free Analog Power/Current Sensor Compatible With High-Voltage Switching DC–DC Converter.

Author

Singh, Shrikant, Mandal, Debashis, Bakkaloglu, Bertan, and Kiaei, Sayfe

Subjects

*COMPLEMENTARY metal oxide semiconductors, *SWITCHED capacitor circuits, *ELECTRIC power conversion, *DIGITAL signal processing, *GALVANIC isolation, *CAPACITOR switching, *MAXIMUM power point trackers, *ANALOG multipliers

Abstract

A sensor circuit to measure the output power of a dc–dc boost for photo-voltaic (PV) maximum power point tracking (MPPT) application is presented. The proposed approach obviates the need for a series current sense resistor and a complex current/voltage digitization and multiplication circuitry required for calculating power. Thereby, this technique does not require analog multipliers, analog-to-digital converters, digital signal processor, and FPGA, thus reducing the bill of material, silicon area, and power consumption of the overall system. Additionally, it provides the dc electrical isolation between the high output voltage of the boost converter and the low-voltage integrated CMOS power sensor circuit. The proposed power sensor circuit is implemented using a switched capacitor differentiator and a voltage-to-time converter. This approach results in lower complexity, lower silicon area, lower power consumption, and lower component count for the overall PV MPPT system. Designed in a 180-nm CMOS process, the circuit can operate with a supply voltage of 1.8 V. It achieves a power sense accuracy of 7.6%, occupies a die area of 0.0519 mm2, and consumes a power of 0.748 mW. [ABSTRACT FROM AUTHOR]

Published

2019

2. A High-Voltage-Compliant Current-to-Digital Sensor for DC?DC Converters in Standard CMOS Technology.

Author

Marti-Arbona, Edgar, Mandal, Debashis, Bakkaloglu, Bertan, and Kiaei, Sayfe

Subjects

*PHOTOVOLTAIC power systems, *CONVERTERS (Electronics), *COMPLEMENTARY metal oxide semiconductors, *MAXIMUM power point trackers, *SWITCHING circuits

Abstract

Efficient current, voltage, and power sensing are critical blocks for power management, switching regulators, maximum power point tracking (MPPT) circuit, and motor control. This paper presents a standard CMOS and low-power current-to-digital converter (IDC) that senses the current flowing at high-voltage nodes. The proposed sensor uses a CMOS-switched capacitor circuit to sense a dc–dc converter output current and gives digital output without an analog-to-digital converter (ADC), or the need for high-voltage technologies. Compared to the resistor-based current-sensing methods that require current-to-voltage circuit, gain block, and an ADC converter, the proposed sensor is a low-power integrated circuit that achieves high resolution, lower complexity, and lower power consumption. The IDC circuit is fabricated on a 5 V, 0.7 μm, and three metal CMOS technology and occupied less than 10% area (1 mm2 area) compared to other sensors. It consumes 18 mW that is less than 40% power consumed by other sensors, and its current measurement error is below 0.4%. The proposed IDC circuit has been characterized as standalone and with a boost dc–dc regulator and MPPT for photovoltaic systems. [ABSTRACT FROM AUTHOR]

Published

2017

3. A Mixed-Signal Adaptive Ripple Canceler for Switching Regulators Providing 18 dB-24 dB of Ripple Rejection up to 1 MHz.

Author

Joshi, Kishan, Yang, Zhe, Fu, Chao, Mandal, Debashis, Waterfall, Gregory, and Bakkaloglu, Bertan

Abstract

A mixed-signal adaptive ripple canceller for reducing switching noise and spurious emissions in switching regulators is presented. The proposed mixed-signal ripple suppression technique tracks and cancels the switching noise by utilizing two schemes: A primary mixed-signal adaptive ripple canceller that provides large signal ripple cancellation up to 20 dB, and an auxiliary linear amplifier-based ripple canceller that minimizes the residual ripple content, achieving a combined ripple rejection of 24 dB. Proposed approach operates without the need for external components, reducing overall printed circuit board area without loss of efficiency. The adaptive ripple canceller is designed and fabricated in a 250 nm CMOS process with four levels of metal. The ripple-canceller is integrated with an on-chip buck regulator to characterize its rejection effectiveness. The ripple canceller can also be utilized as a stand-alone ripple cleaner module with an external commercial-off-the-shelf (COTS) switching regulator. The proposed ripple canceller can track and cancel power supply ripple up to 1 MHz with 24 dB rejection and reduces ripple content up to fourth harmonic by at least 20 dB while supporting dc loads up to 1 A and ripple currents up to 350 mApk-pk. The proposed approach achieves 30% lower quiescent current than using a linear low-dropout regulator without the need for any external components. [ABSTRACT FROM AUTHOR]

Published

2020

4. A Low-Noise Output Capacitorless Low-Dropout Regulator With a Switched-RC Bandgap Reference.

Author

Magod, Raveesh, Suda, Naveen, Ivanov, Vadim, Balasingam, Ravi, and Bakkaloglu, Bertan

Subjects

*BAND gaps, *PINK noise, *ENERGY management, *CAPACITORS, *ELECTRIC resistors

Abstract

Low-noise linear regulators are critical for power supply regulation of noise-sensitive circuits, such as ADCs, phase-locked loops, and other mixed-signal/RF system-on-a-chip designs. A low-noise low-dropout (LN-LDO) regulator using switched-RC bandgap reference and a multiloop, unconditionally stable error amplifier for output capacitorless operation is presented in this paper. A sample-and-hold switched-RC filter is developed to reduce the noise of the bandgap reference and drain-side modulated current-mode chopping technique is proposed to reduce the flicker (1/f) noise of the error amplifier. A switched capacitor notch filter is utilized to filter out the residual chopping ripple of the error amplifier. Thermal noise of the current reference circuit which is significant at such low noise levels is also reduced by using a low-area penalty passive RC filter. These techniques reduce the total integrated output noise of the LDO in the 10 Hz to 100 kHz band from $95.3\;\mu {{\rm{V}}_{{\rm{RMS}}}}$ down to $14.8\;\mu {{\rm{V}}_{{\rm{RMS}}}} . The LDO delivers a maximum load current of 100 mA with a dropout voltage of 230 mV and a quiescent current consumption of 40\;\mu \rmA . It achieves a power supply rejection of 50 dB at 10 kHz for a programmable output voltage range of 1–3.3 V. Fabricated in a 0.25\;\mu \rmm CMOS process, the LDO core occupies an area of 0.18 mm2. [ABSTRACT FROM AUTHOR]

Published

2017