Showing total 11 results

1. Area-Efficient Time-Shared Digital-to-Analog Converter With Dual Sampling for AMOLED Column Driver IC’s.

Author

An, Tai-Ji, Hwang, Moon-Sang, Choe, Won-Jun, Ahn, Gil-Cho, and Lee, Seung-Hoon

Subjects

*DIGITAL-to-analog converters, *ORGANIC light emitting diodes, *INTEGRATED circuits

Abstract

This paper presents a 24-channel time-shared 8-bit digital-to-analog converter (DAC) with dual sampling to minimize the effective channel area of the column driver integrated circuit (IC) for high-resolution active-matrix organic light emitting diodes (AMOLED). The proposed time-shared DAC significantly reduces the effective channel area of the column driver IC, since a single high-speed DAC is shared among multi channels. The dual-sampling architecture for the output amplifiers also reduces the power consumption of the column driver IC, where the operating time of the time-shared DAC and the output amplifier is efficiently handled during the limited 1-horizontal time. The sampling accuracy of the dual-sampling architecture is improved by a simple dummy switch and a source follower. The proposed time-shared DAC with the dual sampling is implemented by a 0.13- $\mu \text{m}$ high-voltage complementary metal-oxide-semiconductor process and integrated in a 960-channel column driver IC, while the effective channel area of the column driver IC is 5520 $\mu \text{m}^{2}$. As a result of driving an 11-inch-wide quad extended graphics array AMOLED panel by using the prototype column driver IC, the panel uniformly generates a clear image. [ABSTRACT FROM AUTHOR]

Published

2018

2. An Efficient Self-Powered Piezoelectric Energy Harvesting CMOS Interface Circuit Based on Synchronous Charge Extraction Technique.

Author

Shi, Ge, Xia, Yinshui, Wang, Xiudeng, Qian, Libo, Ye, Yidie, and Li, Qing

Subjects

*ENERGY harvesting, *PIEZOELECTRIC device design & construction, *INTEGRATED circuits, *ELECTROMAGNETIC waves, *WIRELESS sensor networks, *EQUIPMENT & supplies

Abstract

An efficient self-powered synchronous electric charge extraction CMOS interface circuit dedicated to piezoelectric harvesters is proposed in this paper. Self-powered peak detection (PKD) and switch circuits are used to reduce quiescent current so that the backup or pre-charged power can be saved. A new low phase lag (LPL) PKD circuit is designed to improve the synchronous extraction efficiency, which only requires one detection capacitor to perform positive and negative PKD. The circuit can be set at general mode (G-mode) or LPL mode (LPL-mode). Under LPL-mode, the phase lag can be reduced typically by 50%, the synchronous extraction efficiency can obtained up to 94%, while the output power can reach 659~\mu \textW when the piezoelectric transducer original open-circuit voltage V\mathrm{ oc,org}=5 V, which is 3.56 times of that of full-bridge rectifier standard energy harvesting circuit at the maximum power point. The minimum harvesting startup voltage is 1.7 V and is independent of the energy storage capacitor voltage V\mathrm{ DC} . The harvesting efficiency can still reach 71.3% at V\mathrm{ oc,org}=5 V. The size of the active area is 0.5 mm2 in a 0.18- \mu \textm CMOS technology. Circuit may be invoked as a functional block for energy autonomous wireless sensor network node of the Internet of Things. [ABSTRACT FROM PUBLISHER]

Published

2018

3. Design and Analysis of Energy-Efficient Single-Pulse Piezoelectric Energy Harvester and Power Management IC for Battery-Free Wireless Remote Switch Applications.

Author

Lee, Minbok, Yang, Joonseok, Park, Myeong-Jae, Jung, Sung-Youb, and Kim, Jaeha

Subjects

*ENERGY harvesting, *PIEZOELECTRIC devices, *WIRELESS communications, *EQUIPMENT & supplies

Abstract

This paper presents a piezoelectric-based power management solution for battery-free wireless remote switches (BWSs). The proposed BWS IC, including a piezoelectric (PE) energy harvester and a buck converter, can collect the energy generated by a single PE-button press, and then supply that energy to a wireless transmitter to send a message. By combining a rectifier using the synchronized switch harvesting on inductor technique and a 6:1 series–parallel switched-capacitor converter, the proposed PE energy harvester can maximize the collected amount of energy, while supplying it at a low output voltage. In addition, by employing a switching-based start-up scheme and a variable ON-time pulse-frequency modulation scheme, the proposed buck converter can reduce the loss associated with charging the output capacitor during start-up, and then deliver the largest possible energy to the load, while maintaining low voltage ripples and high-power efficiency. A prototype BWS IC fabricated with high-voltage 250-nm CMOS technology was shown to be capable of harvesting a total energy of 246~\mu \textJ from a single button-pressing of a 300-mm2 lead magnesium niobate-lead titanate PE disc. More than 200~\mu \textJ was delivered to the load, sufficient to transmit a 4-B-long message via a 2.4-GHz wireless USB channel over a 10-m distance. [ABSTRACT FROM AUTHOR]

Published

2018

4. On Loss Mechanisms of Complex Switched Capacitor Converters.

Author

Beck, Yuval, Eden, Nir, Sandbank, Shira, Singer, Sigmund, and Smedley, Keyue Ma

Subjects

*CONVERTERS (Electronics), *SWITCHED capacitor networks, *TOPOLOGY, *LOW voltage integrated circuits, *ELECTRIC power conversion

Abstract

In this paper the power losses of efficient capacitive converters with multitude transfer ratio values are discussed. The loss mechanism circuits, based on general transposed series parallel (GTSP) topology, is studied and the losses are calculated, which in turn enables the “bottlenecks” to be identified and overcome. The calculations show that for a given number of switching cells the power losses of such converters are mainly dependent on the voltage conversion ratio, the topology function, the resistances of the switches in on and off states, the ESR of the capacitors, the switching frequency, the voltage drop, and the load. The theory explains the fact that was observed in experiments, that for low voltage conversion ratio values, efficiency decrease was measured. It is shown that for these low voltage ratio values the mechanism associated to the off resistance of the switches is more dominant and reduces the efficiency. This power loss estimation can be used as a powerful tool for the performance optimization of capacitive converters. The theoretical results are verified experimentally on a 10-cell GTSP converter prototype. The experimental results show good agreement with the proposed theory. [ABSTRACT FROM PUBLISHER]

Published

2015

5. A 12-bit 20 MS/s 56.3 mW Pipelined ADC With Interpolation-Based Nonlinear Calibration.

Author

Jie Yuan, Sheung Wai Fung, Kai Yin Chan, and Ruoyu Xu

Subjects

*DATA pipelining, *ANALOG-to-digital converters, *ANALOG electronic systems, *PIPELINED ADCs, *INTEGRATED circuits, *ELECTRONIC circuits

Abstract

The linearity of a high-resolution pipelined analog- to-digital converter (ADC) is mainly limited by the capacitor mismatch and the finite operational amplifier (OPAMP) gain in the multiplying-digital-to-analog converter (MDAC). Therefore, high resolution pipelined ADCs usually require high-gain OPAMP and large capacitors, which causes large ADC power. In recent years, various nonlinear calibration techniques have been developed to compensate both linear and nonlinear error from MDCAs so that low-power MDACs with small capacitors and low-gain OPAMP can be used. Hence, the ADC power can be greatly reduced. This paper introduces a novel interpolation- based digital self-calibration architecture for pipelined ADC. Compared to previous techniques, the new architecture is free of adaptation. Hence, long convergence is not needed. The complexity of the digital processor is also considerably lower. The new architecture does not use backend ADC to measure MDACs. Hence, it is free of the accumulation of measurement error, which leads to more accurate calibration. A prototype ADC with the calibration architecture is fabricated in a 0.35 3.3 V CMOS process. The ADC samples at 20 MS/s. The calibration improves the ADC DNL and INL from 1.47 LSB and 7.85 LSB to 0.2 LSB and 0.27 LSB. For a 590 kHz sinusoidal signal, the calibration improves the ADC signal-to-noise-distortion ratio(SNDR) and spurious-free dynamic range (SFDR) from 41.3 dB and 52.1 dB to 72.5 dB and 84.4 dB respectively. The 11.8-ENOB 20 MS/s ADC consumes 56.3 mW power with 3.3 V supply. The 0.78 pJ/step figure-of-merit (FOM) is low for designs in 0.35 CMOS processes. At the Nyquist frequency, SNDR of the calibrated ADC drops 8 dB due to the slow settling of the first pipeline stage. [ABSTRACT FROM PUBLISHER]

Published

2012

6. Capacitive Transposed Series-Parallel Topology With Fine Tuning Capabilities.

Author

Beck, Yuval and Singer, Sigmond

Subjects

*TOPOLOGY, *INTEGRATED circuits, *INFORMATION technology, *SEMICONDUCTORS, *SWITCHED capacitor circuits, *ELECTRONIC circuits

Abstract

A general transposed series-parallel topology of a switched-capacitor converter is presented and analyzed in this paper. This topology evolved from the conventional series-parallel through rectangular matrices based topologies to partial arbitrary matrices which are constructed of different size strings of capacitors to arbitrary matrices, based on a bank of equally valued capacitors. Theoretically, these topologies have a large number of dc/dc voltage ratios, which lead to the capability to achieve very accurate fixed dc/dc voltage ratios. These topologies also have the capability for “fine tuning” when voltage regulation is necessary. For the general transposed series-parallel topology, it is shown that the number of possible dc/dc voltage transfer ratios escalates exponentially with an addition of each capacitor as the sum of partition functions. Therefore, relatively fewer components are required for an assumed accurate voltage ratio. Dispersion of parameters in the capacitance value is considered. Small ripple analysis, losses calculations and efficiency considerations are also discussed. Simulations are performed for 2.2 and 2.25 voltage ratios. The simulations are in good agreement with the theoretical calculations. [ABSTRACT FROM PUBLISHER]

Published

2011

7. Unified Frequency-Domain Analysis of Switched-Series-RC Passive Mixers and Samplers.

Author

Soer, Michiel C. M., Klumperink, Eric A. M., de Boer, Pieter-Tjerk, van Vliet, Frank E., and Nauta, Bram

Subjects

*ELECTRIC noise, *INTEGRATED circuits, *KERNEL functions, *TRANSFER functions, *ELECTRIC resistors

Abstract

A wide variety of voltage mixers and samplers are implemented with similar circuits employing switches, resistors, and capacitors. Restrictions on duty cycle, bandwidth, or output frequency are commonly used to obtain an analytical expression for the response of these circuits. This paper derives unified expressions without these restrictions. To this end, the circuits are decomposed into a polyphase multipath combination of single-ended or differential switched-series-RC kernels. Linear periodically time-variant network theory is used to find the harmonic transfer functions of the kernels and the effect of polyphase multipath combining. From the resulting transfer functions, the conversion gain, output noise, and noise figure can be calculated for arbitrary duty cycle, bandwidth, and output frequency. Applied to a circuit, the equations provide a mathematical basis for a clear distinction between a “mixing” and a “sampling” operating region while also covering the design space “in between.” Circuit simulations and a comparison with mixers published in literature are performed to support the analysis. [ABSTRACT FROM PUBLISHER]

Published

2010

8. A 70-to-2 V Triboelectric Energy Harvesting System Utilizing Parallel-SSHI Rectifier and DC-DC Converters.

Author

Kara, Ismail, Becermis, Mustafa, Kamar, Mohamed Abdel-Aal, Aktan, Mustafa, Dogan, Hakan, and Mutlu, Senol

Subjects

*ENERGY harvesting, *TRIBOELECTRICITY, *CAPACITOR switching, *OPEN-circuit voltage, *INTEGRATED circuits, *HIGH voltages, *WHEAT harvesting, *HARVESTING

Abstract

In this article, first integrated circuit (IC) implementation of parallel synchronized switching harvesting on inductor (p-SSHI) is presented for triboelectric energy harvester targeting 1 Hz to 5 Hz mechanical motions. It is accompanied by on-chip buck and switched capacitor DC-DC converters, all capable of handling 70 V levels. Unlike piezoelectric harvesters, triboelectric nanogenerators (TENGs) can produce very high open-circuit voltages; thus, the proposed system utilizes this property within the technology limits to maximize the extracted power. An in-house manufactured TENG using steel and polytetrafluoroethylene (PTFE) is modeled for sub-5 Hz motions. The energy is extracted and stored in an external capacitance until its voltage reaches 70 V, which is achieved in three press-and-release mechanical cycles. 70-to-2 V down conversion is carried on by 70-to-10 V buck converter followed by a 10-to-2 V switched capacitor DC-DC converter. A chip is manufactured in $0.18~\mu \text{m}$ HV BCD process with an active area of 6.25 mm2. End-to-end peak efficiency is measured as 32.71% for 1 Hz motion with a 722 $\mu \text{W}$ total power delivery to the load for 4 ms. [ABSTRACT FROM AUTHOR]

Published

2021

9. A 1 pF-to-10 nF Generic Capacitance-to-Digital Converter Using Zero-Crossing $\Delta\Sigma$ Modulation.

Author

Li, Bing, Wang, Wei, Liu, Jia, Liu, Wen-Jun, Yang, Qian, and Ye, Wen-Bin

Subjects

*INTEGRATED circuits, *ELECTRONIC circuits

Abstract

Conventional capacitance-to-digital converters (CDCs) suffer limitations either on narrow capacitance range or low resolution for jitter-induced noise and high power consumption. In order to avoid these limitations, a 13-b 1 pF–10 nF generic CDC is presented. In the proposed CDC with the oversampled $\Delta \Sigma $ modulation, the zero-crossing-based circuits (ZCBCs) are used to replace the operational transconductance amplifier to avoid feedback loop stability issues. However, the ZCBCs inevitably incur the non-idealities and thus, a novel calibration scheme is presented for efficient non-ideality-error cancellation. In addition, for the purpose of making the proposed CDC sufficiently intelligent to adapt to a wide capacitance-sensing range, an adaptive auto-range mechanism is proposed. The above three techniques complement each other and work as a whole leading to the proposed CDC with wide range, high resolution, high linearity, and low power consumption. A prototype fabricated using 0.18- $\mu \text{m}$ CMOS technology is experimentally verified using a MEMS capacitive humidity sensor. The measurement results show that the CDC achieves a 13-b root-mean-square noise equivalent resolution with a 128- $\mu \text{s}$ conversion time and a 230 fJ/conversion-step figure of merit. The calibration scheme enhances the linearity from 7 to 11.4 b in the 1 pF–10 nF compatible capacitance range. [ABSTRACT FROM AUTHOR]

Published

2018

10. 4-Phase Interleaved Boost Converter With IC Controller for Distributed Photovoltaic Systems.

Author

Pulvirenti, Francesco, La Scala, Amedeo, Ragonese, Domenico, D'Souza, Keith, Tina, Giuseppe M., and Pennisi, Salvatore

Subjects

*PHOTOVOLTAIC power generation, *CODING theory, *DISTRIBUTED power generation, *ELECTRIC power conversion, *MAXIMUM power transfer theorem, *CONVERTERS (Electronics)

Abstract

We present a DC-DC converter for photovoltaic (PV) applications that is suitable for distributed power conversion obtained by transferring part of the electronics from the inverter to the module. The proposed circuit implements a high-efficiency four-phase interleaved boost converter employing relatively low-valued inductive and capacitive components. Its compact realization is made possible thanks to the innovative design of a dedicated integrated circuit (IC) embedding the power MOS switches and performing the converter control section as well as the Maximum Power Point Tracking (MPPT) algorithm. The solution is designed for a maximum delivered power of 300 W and to work with an MPPT voltage between 9 V and 36 V, with maximum allowed panel current of 9 A. The area of the complete printed-circuit board is 4 cm\,\times\,7 cm. Experimental measurements show that the average power conversion efficiency is between 93% and 99% and that the MPPT efficiency is always greater than 99.7%. [ABSTRACT FROM PUBLISHER]

Published

2013

11. An Analog Sub-Miliwatt CMOS Image Sensor With Pixel-Level Convolution Processing.

Author

Jendernalik, W., Blakiewicz, G., Jakusz, J., Szczepanski, S., and Piotrowski, R.

Subjects

*PIXELS, *COMPLEMENTARY metal oxide semiconductors, *INTEGRATED circuits, *SYSTEMS design, *IMAGE processing, *ENERGY dissipation

Abstract

A new approach to an analog ultra-low power medium-resolution vision chip design is presented. The prototype chip performs low-level image processing algorithms in real time. Only a photo-diode, MOS switches and two capacitors are used to create an analog processing element (APE) that is able to realize any convolution algorithm based on a full 3\,\times\,3 kernel. The proof-of-concept circuit is implemented in 0.35 \mum CMOS technology, and contains a 64\,\times\,64 SIMD matrix with embedded APEs. The matrix dissipates less than 0.3 mW (less than 0.1 \muW per APE) of power under 3.3 V supply, and its image processing speed is up to 100 frames/s. [ABSTRACT FROM AUTHOR]

Published

2013