A Charge Pump Current Mismatch Compensation Design for Sub-Sampling PLL

Abstract In recent years, there have been many advances in the equipment and techniques used to isolate faults. There are many options available to the failure analyst. The available techniques fall into the categories of electrical, photonic, thermal and electron/ion beam [1]. Each technique has its advantages and its limitations. In this paper, we introduce a case of successful failure analysis using a combination of several fault localization techniques on a 0.15um CMOS device with seven layers of metal. It includes electrical failure mode characterization, front side photoemission, backside photoemission, Focused Ion Beam (FIB), Scanning Electron Microscope (SEM) and liquid crystal. Electrical characterization along with backside photoemission proved most useful in this case as a poly short problem was found to be causing a charge pump failure. A specific type of layout, often referred to as a hammerhead layout, and the use of Optical Proximity Correction (OPC) contributed to the poly level shorts.

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The Design of a Charge Pump Circuit and System with Input Impedance Modulation for a Flexible-Type Thermoelectric Generator with High-Output Impedance

Electronics ◽

10.3390/electronics10101212 ◽

2021 ◽

Vol 10 (10) ◽

pp. 1212

Author(s):

Kazuma Koketsu ◽

Toru Tanzawa

Keyword(s):

Input Impedance ◽

Thermoelectric Generator ◽

Charge Pump ◽

Operating Voltage ◽

Output Impedance ◽

Two Phase ◽

Pump System ◽

High Output Impedance ◽

A Charge ◽

High Output

This paper describes a charge pump system for a flexible thermoelectric generator (TEG). Even though the TEG has high-output impedance, the system controls the input voltage to keep it higher than the minimum operating voltage by modulating the input impedance of the charge pump using two-phase operation with low- and high-input impedance modes. The average input impedance can be matched with the output impedance of the TEG. How the system can be designed is also described in detail. A design demonstration was performed for the TEG with 400 Ω. The fabricated system was also measured with a flexible-type TEG based on carbon nanotubes. Even with an output impedance of 1.4 kΩ, the system converted thermal energy into electric power of 30 μW at 2.5 V to the following sensor ICs.

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A Charge-Pump-Based SIMO Buck-Boost DC-DC Converter with Three Operation Modes

2021 IEEE International Symposium on Circuits and Systems (ISCAS) ◽

10.1109/iscas51556.2021.9401624 ◽

2021 ◽

Author(s):

Zhiguo Tong ◽

Peng Cao ◽

Peng Xu ◽

Dehong Lv ◽

Danzhu Lu ◽

...

Keyword(s):

Charge Pump ◽

Operation Modes ◽

A Charge

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A Charge Pump Circuit --- Cascading High-Voltage Clock Generator

4th IEEE International Symposium on Electronic Design, Test and Applications (delta 2008) ◽

10.1109/delta.2008.94 ◽

2008 ◽

Cited By ~ 6

Author(s):

Wen Chang Huang ◽

Jin Chang Cheng ◽

Po Chih Liou

Keyword(s):

High Voltage ◽

Charge Pump ◽

Clock Generator ◽

A Charge ◽

Charge Pump Circuit

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A Charge-Pump-Based Current Feedback Method for AMOLED Displays

Journal of Display Technology ◽

10.1109/jdt.2013.2279885 ◽

2013 ◽

Vol 9 (10) ◽

pp. 783-786 ◽

Cited By ~ 6

Author(s):

Chih-Lung Lin ◽

Fu-Chieh Chang ◽

Po-Chun Lai ◽

Po-Syun Chen ◽

Wen-Yen Chang

Keyword(s):

Charge Pump ◽

Current Feedback ◽

Feedback Method ◽

A Charge

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Design and Implementation of Charge Pump Phase-Locked Loop Frequency Source Based on GaAs pHEMT Process

Sensors ◽

10.3390/s22020504 ◽

2022 ◽

Vol 22 (2) ◽

pp. 504

Author(s):

Ranran Zhao ◽

Yuming Zhang ◽

Hongliang Lv ◽

Yue Wu

Keyword(s):

Maximum Output Power ◽

Charge Pump ◽

Phase Locked Loop ◽

Low Noise ◽

Signal Frequency ◽

Maximum Output ◽

Voltage Controlled Oscillator ◽

Chip Area ◽

Frequency Source ◽

A Charge

This paper realized a charge pump phase locked loop (CPPLL) frequency source circuit based on 0.15 μm Win GaAs pHEMT process. In this paper, an improved fully differential edge-triggered frequency discriminator (PFD) and an improved differential structure charge pump (CP) are proposed respectively. In addition, a low noise voltage-controlled oscillator (VCO) and a static 64:1 frequency divider is realized. Finally, the phase locked loop (PLL) is realized by cascading each module. Measurement results show that the output signal frequency of the proposed CPPLL is 3.584 GHz–4.021 GHz, the phase noise at the frequency offset of 1 MHz is −117.82 dBc/Hz, and the maximum output power is 4.34 dBm. The chip area is 2701 μm × 3381 μm, and the power consumption is 181 mw.

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