Samsung electronics co., ltd. (20240322677). METHOD FOR PERFORMING A CHARGE-SHARING OPERATION AND A CHARGE PUMP CIRCUIT THEREFOR simplified abstract
Contents
METHOD FOR PERFORMING A CHARGE-SHARING OPERATION AND A CHARGE PUMP CIRCUIT THEREFOR
Organization Name
Inventor(s)
Ravindra Kumar Singh of Bengaluru (IN)
Mihir Dhagat of Bengaluru (IN)
Subodh Prakash Talgor of Bengaluru (IN)
METHOD FOR PERFORMING A CHARGE-SHARING OPERATION AND A CHARGE PUMP CIRCUIT THEREFOR - A simplified explanation of the abstract
This abstract first appeared for US patent application 20240322677 titled 'METHOD FOR PERFORMING A CHARGE-SHARING OPERATION AND A CHARGE PUMP CIRCUIT THEREFOR
The present disclosure pertains to a charge pump circuit featuring a six-phase clock. The circuit includes a six-phase clock circuit and a gate boosting charge pump that receives multiple clock signals from the six-phase clock circuit. The six-phase clock circuit generates six clock signals, providing a dead time between each signal. The gate boosting charge pump enables charge-sharing operations to distribute charges among parasitic capacitors efficiently.
- The charge pump circuit has a six-phase clock configuration.
- The gate boosting charge pump facilitates charge-sharing operations among parasitic capacitors.
- The six-phase clock circuit generates six clock signals with dead time intervals.
- The innovation optimizes charge distribution and efficiency in the circuit.
- The technology enhances the performance of charge pump circuits in electronic devices.
Potential Applications: - Integrated circuits - Power management systems - Battery charging circuits
Problems Solved: - Efficient charge distribution - Enhanced performance of charge pump circuits - Improved power management in electronic devices
Benefits: - Increased efficiency in charge pump circuits - Enhanced power management capabilities - Improved overall performance of electronic devices
Commercial Applications: Title: Advanced Charge Pump Circuit for Enhanced Power Management This technology can be utilized in various electronic devices such as smartphones, tablets, and laptops to improve power management efficiency and overall device performance. It can also be integrated into power management systems in industrial applications for enhanced energy efficiency.
Prior Art: Researchers can explore prior patents related to charge pump circuits, clock signal generation, and charge-sharing operations to understand the evolution of this technology.
Frequently Updated Research: Researchers are continually exploring ways to optimize charge pump circuits for improved efficiency and performance. Stay updated on the latest advancements in power management systems and integrated circuits to leverage the full potential of this technology.
Questions about Charge Pump Circuits: 1. How does the six-phase clock configuration improve the efficiency of the charge pump circuit? The six-phase clock configuration allows for precise timing and distribution of charges, enhancing the overall performance of the circuit.
2. What are the potential challenges in implementing gate boosting charge pumps in electronic devices? Implementing gate boosting charge pumps may require careful design considerations to ensure compatibility with existing circuitry and optimize performance.
Original Abstract Submitted
the present disclosure relates to a charge pump circuit with a six-phase clock. the charge pump circuit comprises a six-phase clock circuit and a gate boosting charge pump configured to receive a plurality of clock signals from the six-phase clock circuit. the six-phase clock circuit includes provides a first clock signal, a second clock signal, a third clock signal, a fourth clock signal, a fifth clock signal, and a sixth clock signal. the gate boosting charge pump is configured to enable a charge-sharing operation to share the stored amount of charges between a plurality of parasitic capacitors. the six-phase clock circuit is configured to provide a dead time between each of the first, second, third, fourth, fifth and sixth clock.