Digital zero-current switching lock-in controller IC for optimized operation of resonant switched-capacitor converters (SCCs)

The invention claimed is: 1 . A digital lock-in controller for a resonant-type converter with one or more sub-circuits having resonant tanks and one or more flying capacitors connected across said resonant tanks, comprising: a) an auto-tuner that receives as input Zero-Current Detect (ZCD) signals and implements a tuning algorithm by performing arithmetic operations that ensure Zero-Current Switching (ZCS) operation for all resonant tanks in said converter; b) a digital High-Resolution (HR) sequencer that receives as input switching-times commands and generates a pulse-width-modulated drive signal that is fed into at least one gate of at least one switching transistor of said converter; c) a sampling block with time resolution of a single delay-element, for accurately reading outputs of at least one ZCD sensor including said ZCD signals; and d) a governor module for performing synchronization actions and dictating an operation mode of the controller, based on auxiliary configurations, wherein Zero-Current Switching (ZCS) operation for all resonant tanks in said converter is performed by: initiating a delay estimation procedure for estimating an inherent delay, being the minimum delay between gating signals of said controller and a sampling command that acquires a valid reading from the at least one ZCD sensor, between the gating signals of said controller by sampling the at least one ZCD sensor, once every switching cycle in different locations; applying a pre-defined switching frequency is to each resonant tank, until early-switching reading from the at least one ZCD sensor is acquired; performing turn-off of power transistors upon start-up and every Nest switching cycles, to thereby consider variations of passive components and clamp the voltage at the switching nodes, when the power transistors are turned-off at the end of a charging phase, wherein a lock-in process to resonance characteristics of each resonant tank comprises: a) operating according to user configurable gating-signals without compensation for a pre-determined number of switching-cycles; b) upon start-up, calculating an inherent delay between the controller and the said converter's transistors; c) sampling the at least one ZCD sensor to obtain early or late switching-state of each resonant tank; d) calculating an error signal based on the acquired switching-state of said converter; e) modifying the duration of the switching cycle for each resonant tank by: i) increasing the duration in case early-switching is acquired; or ii) decreasing the duration in case late-switching is acquired; f) calculating the converters switching period based on the results of step e) above; g) updating the gating-signals for each resonant-tank; and h) repeating steps c)-f) above, until the controller is disabled, wherein a sampling operation performed by the sampling block is executed as: a) a synchronous procedure utilizing a system's internal clock for compensating the inherent delay with the resolution of said internal clock, by performing continuous sampling of the at least one ZCD sensor at the internal clock's frequency from a turn-off command by the controller, until the end of an applied dead-time and processing the samples to acquire the converter's switching-state; or b) an asynchronous procedure combining the system's internal clock and a delay-line based module for high-resolution sampling with time-resolution of a single delay-element, where, the converter's switching-state is accurately acquired, based on an estimated inherent delay upon start-up, using a single sampling operation, wherein, once a dead-time period is over, the sampling block provides the auto-tuner with valid readings of the at least one ZCD sensor. 2 . The controller according to claim 1 , in which the resonant-type converter is a Resonant Switched-Capacitor Converter (RSCC). 3 . The controller according to claim 2 , in which the auto-tuner is adapted to tune a switching time of each sub-circuit by receiving as input the ZCD signals and outputting the following auxiliary signals: a) a digital word representing the switching time for each sub-circuit of a Resonant Switched-Capacitor Converter (RSCC), where Most Significant Bits (MSBs) of said digital word corresponds to the coarse part of a drive signal to at least one RSCC transistor with time-resolution of a system's clock switching period and Least Significant Bits (LSBs) of said digital word represents the fine part of said pulse-width-modulated drive signal with time resolution being equal to a delay of a single delay element; and b) a digital signal indicating a lock-in state of the controller by performing: i) inherent delay calculation during start-up; ii) a lock-in to the correct switching-time of each sub-circuit; iii) in-process of the lock-in to the correct switching-time of one or more sub-circuits. 4 . The controller according to claim 1 , in which the auto-tuner comprises: a) a digital compensation unit for evaluating the ZCD signals and determining a required modification of switching times; b) a digital Low-Pass Filter (LPF) for smoothing noise variations and inaccurate reading of the at least one ZCD sensor; and c) a digital logic block for producing a digital representation of the lock-in state of the controller while being locked. 5 . The controller according to claim 1 , in which the digital HR sequencer is adapted to: a) receive as inputs the switching-times commands for each sub-circuit and a user configurable dead-time; b) control the dead time for each resonant tank with respect to all other active resonant tanks; and c) output the pulse-width-modulated drive signal to the at least one RSCC transistor with time resolution of a single delay-element. 6 . The controller according to claim 1 , in which the sampling operation is executed by the sampling block independently, for each sub-circuit of the RSCC. 7 . The controller according to claim 1 , in which the Governor module is adapted to: a) receive as input the auxiliary configuration from a single-pin based Sigma-Delta Analog-To-Digital Converter (SD-ADC) configuration circuit; b) dictate the desired operation mode of the converter, based on the said auxiliary configuration, by executing: c) a start-up routine for calculating the inherent delay; d) a light-load operation, during which sampling and tuning operations are not carried out on a cycle-by-cycle basis to minimize power consumption; and e) a normal operation mode, wherein synchronization actions performed by said Governor are based on the system's internal clock and based on information regarding the tuning process provided by the Auto-Tuner block, while being Locked. 8 . A method for controlling a resonant-type converter with one or more resonant tanks and one or more flying capacitors connected across said resonant tanks, comprising: a) performing, by an auto-tuner that receives as input Zero-Current Detect (ZCD) signals, arithmetic operations that ensure Zero-Current Switching (ZCS) operation for all resonant tanks in said converter, to implement a tuning algorithm; b) generating, by a digital High-Resolution (HR) sequencer that receives as input the switching-times commands, a pulse-width-modulated drive signal that is fed into at least one gate of at least one switching transistor of said converter; c) accurately reading of the outputs of at least one ZCD sensor by a sampling block with time resolution of a single delay-element; and d) performing synchronization actions and dictating the operation mode during control operation, based on auxiliary configurations, wherein Zero-Current Switching (ZCS) operation for all resonant tanks in said converter is performed by: i