Abstract: A method of eliminating reference voltage of Analog-to-Digital Converter to enhance faster conversion rate, achieve compact size and decrease power consumption for Successive Approximation Register (SAR) Analog-to-Digital Converter (ADC).

Abstract: A method of expanding current steering Digital-to-Analog Converter (DAC) output amplitude and enhancing linearity performance. Level shifters with regulated supply and ground voltage are inserted before current source latches. Extra devices and small current are placed between switches and resistor load to enhance the linearity of current steering DAC.

Abstract: A method of expanding current steering Digital-to-Analog Converter (DAC) output amplitude and enhancing linearity performance. Level shifters with regulated supply and ground voltage are inserted before current source latches. Extra devices and small current are placed between switches and resistor load to enhance the linearity of current steering DAC.

Abstract: Computing-in-memory utilizes memory as weight for multiply-and-accumulate (MAC) operations. Input data multiplies weights to produce output data during the operation. Method of data conversion from input data, memory element to output data is described to enhance the computing efficiency.

Abstract: Computing-in-memory utilizes memory as weight for multiply-and-accumulate (MAC) operations. Input data multiplies weights to produce output data during the operation. Method of data conversion from input data, memory element to output data is described to enhance the computing efficiency.

Abstract: A method of enhancing SAR ADC conversion rate by employing a new value shifted capacitor DAC. The value shifted capacitor DAC decreases largest capacitor to improve the reference voltage settling. The reduction of capacitor is added back onto the smaller capacitor DAC to maintain the same total capacitor value. The binary search outputs are re-combined and processed to produce final binary ADC outputs. The overhead of using value shifted capacitor DAC is the extra latency needed for re-combined logic.

Abstract: A new SARADC has two low resolution SAR (Successive Approximation Register) ADCs coupled together by an amplifier to increase the overall resolution and enhance ADC conversion rate. The gain reduction of amplifier is corrected by shifting the digital binary output position. Two SAR ADC outputs are timing aligned and summed to produce final high-resolution high conversion rate ADC output.

Abstract: A method of enabling full speed test and characterization for high-speed Digital-to-Analog Converter (DAC) by employing an on-chip pattern generator. The test pattern is written to the on-chip pattern generator through a low data rate Integrated circuit (IC) interface, and the pattern generator is then enabled and coupled to DAC to facilitate full speed test for DAC. This method does not require extra input/output pin or extra process and minimize design complexity.

Abstract: Systems and methods are disclosed for Successive Approximation Register Analog-to-Digital Converter (SAR ADC) by coupling an ADC capacitive network coupled to a comparator; and performing binary search using a comparator output using a capacitive DAC calibration process to enhance SAR ADC linearity and performance. In one implementation, the calibration process starts with the least significant bit (LSB) capacitor calibration then proceed to higher bit capacitors until all the capacitors are calibrated. Each capacitor consists of fixed-value base capacitor and value-adjustable capacitor. The capacitor calibration logic is implemented based on the process then incorporated into SAR ADC. ADC performs capacitor calibration first before normal conversion operation. The non-ideal aspect of normal conversion operation is preserved and accounted during capacitor calibration.

Abstract: Systems and methods are disclosed for Successive Approximation Register Analog-to-Digital Converter (SAR ADC) by coupling an ADC capacitive network coupled to a comparator; and performing binary search using a comparator output using a capacitive DAC calibration process to enhance SAR ADC linearity and performance. In one implementation, the calibration process starts with the least significant bit (LSB) capacitor calibration then proceed to higher bit capacitors until all the capacitors are calibrated. Each capacitor consists of fixed-value base capacitor and value-adjustable capacitor. The capacitor calibration logic is implemented based on the process then incorporated into SAR ADC. ADC performs capacitor calibration first before normal conversion operation. The non-ideal aspect of normal conversion operation is preserved and accounted during capacitor calibration.

Abstract: A method of incorporating Programmable Gain Amplifier (PGA) function into pipelined ADC for wide input range. The power consumption is saved without adding extra stage to reduce input range. The ADC input range can be adjusted on the fly using resistor bank and capacitor bank to achieve optimal system performance.

Abstract: A method of enhancing SAR ADC performance includes employing PVT processor to correct process, voltage and temperature (PVT) variation. The PVT processor senses process, supply voltage and temperature information then maximize the time for SAR binary search process. The PVT processor first applies coarse optimization to correct process and voltage variation then applies fine optimization to correct the temperature variation. The SAR ADC is operated at its optimized PVT condition and its performance is enhanced after PVT optimization.

Abstract: A method of enhancing SAR ADC performance includes employing PVT processor to correct process, voltage and temperature (PVT) variation. The PVT processor senses process, supply voltage and temperature information then maximize the time for SAR binary search process. The PVT processor first applies coarse optimization to correct process and voltage variation then applies fine optimization to correct the temperature variation. The SAR ADC is operated at its optimized PVT condition and its performance is enhanced after PVT optimization.

Abstract: A method of enhancing SAR ADC conversion rate by employing a new value shifted capacitor DAC. The value shifted capacitor DAC decreases largest capacitor to improve the reference voltage settling. The reduction of capacitor is added back onto the smaller capacitor DAC to maintain the same total capacitor value. The binary search outputs are re-combined and processed to produce final binary ADC outputs. The overhead of using value shifted capacitor DAC is the extra latency needed for re-combined logic.

Abstract: A method of incorporating Programmable Gain Amplifier (PGA) function into pipelined ADC for wide input range. The power consumption is saved without adding extra stage to reduce input range. The ADC input range can be adjusted on the fly using resistor bank and capacitor bank to achieve optimal system performance.

Abstract: Systems and methods are disclosed for Successive Approximation Register Analog-to-Digital Converter (SAR ADC) by coupling an ADC capacitive network coupled to a comparator; and performing binary search using a comparator output using a capacitive DAC calibration process to enhance SAR ADC linearity and performance. In one implementation, the calibration process starts with the least significant bit (LSB) capacitor calibration then proceed to higher bit capacitors until all the capacitors are calibrated. Each capacitor consists of fixed-value base capacitor and value-adjustable capacitor. The capacitor calibration logic is implemented based on the process then incorporated into SAR ADC. ADC performs capacitor calibration first before normal conversion operation. The non-ideal aspect of normal conversion operation is preserved and accounted during capacitor calibration.

Abstract: A method of enhancing SAR ADC performance includes employing PVT processor to correct process, voltage and temperature (PVT) variation. The PVT processor senses process, supply voltage and temperature information then maximize the time for SAR binary search process. The PVT processor first applies coarse optimization to correct process and voltage variation then applies fine optimization to correct the temperature variation. The SAR ADC is operated at its optimized PVT condition and its performance is enhanced after PVT optimization.

Abstract: Systems and methods of restraining reverse engineering process for analog integrated circuit use techniques of adding dummy devices, device fragmentation, increasing bus width, employing different layouts for the same circuit element and mixing different types of passive devices increase complexity and makes the layout floorplan more difficult to be extracted for the reverse engineering. The system adds dummy devices and ensures the extra devices and capacitance do not affect the target circuit performance.

Abstract: Systems and methods of restraining reverse engineering process for analog integrated circuit use techniques of adding dummy devices, device fragmentation, increasing bus width, employing different layouts for the same circuit element and mixing different types of passive devices increase complexity and makes the layout floorplan more difficult to be extracted for the reverse engineering. The system adds dummy devices and ensures the extra devices and capacitance do not affect the target circuit performance.

Abstract: A method of increasing SAR ADC conversion rate and reducing power consumption by employing a new timing scheme and minimizing timing delay for each bit-test during binary-search process. The high frequency clock input requirement is eliminated and higher speed rate can be achieved in SAR ADC.