Abstract: A converter unit to improve overall recovered power in a photovoltaic array configuration. Each photovoltaic panel in the photovoltaic array may be coupled to a respective converter unit, which may include a controller to sense an output voltage and output current produced by the solar panel, and manage the output voltage of a corresponding power converter to optimize and regulate the resultant bus voltage to a point which reduces overall system losses, maintains a low loss condition, and removes series-string non-idealities when the panels are series connected. The controller may also adapt to output condition constraints. Instead of single-port regulation, a combination of input voltage and output voltage management and regulation may be performed within the converter. The source voltage and current characteristic may be shaped to correspond to an optimized power curve at the desired bus voltage to allow MPPT tracking according to the DC voltage bus.

Abstract: A converter unit configured to couple to a photovoltaic panel (PV) may include a controller to sense an output voltage and output current produced by the photovoltaic panel, and manage the output voltage of a corresponding power converter coupled to a DC bus to regulate the resultant bus voltage to a point that reduces overall system losses, and removes non-idealities when the panels are series connected. The controller may also adapt to output condition constraints, and perform a combination of input voltage and output voltage management and regulation, including maximum power point tracking (MPPT) for the PV. The output voltage and output current characteristic of the power converter may be shaped to present a power gradient—which may be hysteretically controlled—to the DC bus to compel an inverter coupled to the DC bus to perform its own MPPT to hold the DC-bus voltage within a determinate desired operating range.

Abstract: A converter unit to improve the response dynamics and overall recovered power in a photovoltaic array configuration. Each photovoltaic panel in the photovoltaic array may be coupled to a respective converter unit, which may include a controller to sense an output voltage and output current produced by the solar panel, and control operation of a power converter to output modified voltage and current corresponding to the solar panel onto a bus coupling the converter units. The controller may operate as an analog or (digital) firmware control system to regulate the input voltage of each power converter unit under indirect guidance of a Maximum Power Point Tracking (MPPT) controller to optimize and regulate the resultant power, and achieve very fast dynamic response to environmental transients.

Abstract: A converter unit configured to couple to a photovoltaic panel (PV) may include a controller to sense an input voltage and input current obtained from the photovoltaic panel, and manage the output voltage of a corresponding power converter coupled to a DC bus to regulate the resultant bus voltage to a point that reduces overall system losses, and removes non-idealities when the panels are series connected. The controller may also perform input voltage management and regulation, including maximum power point tracking (MPPT) for the PV. The controller may probe the bus voltage using a probe waveform generated according to a pseudo-random bit sequence (PRBS), to provide a probe signal that is distinct from the control steps performed by the controller. A PV array may feature a respective converter unit coupled to each PV, with each respective controller using a different and unique seed for generating its PRBS.

Abstract: A module for connecting (or coupling) and disconnecting (or decoupling) a photovoltaic panel (PV) to and from other PV panels in a string of PV panels. The module may include first circuitry for detecting when a voltage output by the PV panel (Vpanel) collapses, and second circuitry for disconnecting the PV panel from the panel string while preventing a transistor switching device (e.g. a power MOSFET) performing the disconnecting (decoupling) operation from entering the linear operating region. The combination of low-voltage detection in the first circuitry, and latching-switching in the second circuitry ensures that the power MOSFET is either fully turned on, coupling the PV panel to the panel string, or fully turned off, decoupling the PV panel from the panel string. The PV panel may be recoupled to the PV string through a connection-check mechanism that reengages the PV panel once Vpanel has returned to normal operating levels.

Abstract: A converter unit configured to couple to a photovoltaic panel may include a controller that monitors: an output voltage and output current obtained from the photovoltaic panel by a switching power core within the converter unit, and an output voltage and output current produced by the switching power core. The controller may calculate a desired duty-cycle value based on the monitored values, and implement a mapping algorithm that translates the duty-cycle value to a pulse-width value and a modulus value. The pulse-width value and the modulus value may be used to simultaneously respectively modulate the pulse-width and pulse-period of a pulse-width modulated (PWM) signal, while maintaining an appropriate linear final duty-cycle ratio between the pulse-width and the pulse-period of the PWM signal. The PWM signal may be provided to the switching power core to control the switching of the switching power core.

Abstract: A photovoltaic (PV) array system may include multiple PV strings, each PV string including respective PV panels coupled in series. Each PV string may be coupled in series with a first terminal of a respective string equalizer module. The string equalizer module may equalize a maximum power-point voltage (VMP) of the PV string before the PV strings combine to produce a single, composite DC bus voltage on a DC bus. To accomplish this, each string equalizer module may generate a respective adaptive string equalizer output voltage at its first terminal to tune a respective PV string voltage of its corresponding respective PV string to have the VMP of its corresponding PV string match respective VMP's of other PV strings. That is, PV strings may sink or source power from/to other PV strings, to equalize the VMP of each corresponding respective PV string.

Abstract: A converter unit configured to couple to a photovoltaic panel (PV) may include a controller to sense an output voltage and output current produced by the photovoltaic panel, and manage the output voltage of a corresponding power converter coupled to a DC bus to regulate the resultant bus voltage to a point that reduces overall system losses, and removes non-idealities when the panels are series connected. The controller may also adapt to output condition constraints, and perform a combination of input voltage and output voltage management and regulation, including maximum power point tracking (MPPT) for the PV. The output voltage and output current characteristic of the power converter may be shaped to present a power gradient—which may be hysteretically controlled—to the DC bus to compel an inverter coupled to the DC bus to perform its own MPPT to hold the DC-bus voltage within a determinate desired operating range.

Abstract: A converter unit configured to couple to a photovoltaic panel may include a controller that monitors: an output voltage and output current obtained from the photovoltaic panel by a switching power core within the converter unit, and an output voltage and output current produced by the switching power core. The controller may calculate a desired duty-cycle value based on the monitored values, and implement a mapping algorithm that translates the duty-cycle value to a pulse-width value and a modulus value. The pulse-width value and the modulus value may be used to simultaneously respectively modulate the pulse-width and pulse-period of a pulse-width modulated (PWM) signal, while maintaining an appropriate linear final duty-cycle ratio between the pulse-width and the pulse-period of the PWM signal. The PWM signal may be provided to the switching power core to control the switching of the switching power core.

Abstract: A converter unit configured to couple to a photovoltaic panel (PV) may include a controller to sense an input voltage and input current obtained from the photovoltaic panel, and manage the output voltage of a corresponding power converter coupled to a DC bus to regulate the resultant bus voltage to a point that reduces overall system losses, and removes non-idealities when the panels are series connected. The controller may also perform input voltage management and regulation, including maximum power point tracking (MPPT) for the PV. The controller may probe the bus voltage using a probe waveform generated according to a pseudo-random bit sequence (PRBS), to provide a probe signal that is distinct from the control steps performed by the controller. A PV array may feature a respective converter unit coupled to each PV, with each respective controller using a different and unique seed for generating its PRBS.

Abstract: A converter unit to improve overall recovered power in a photovoltaic array configuration. Each photovoltaic panel in the photovoltaic array may be coupled to a respective converter unit, which may include a controller to sense an output voltage and output current produced by the solar panel, and manage the output voltage of a corresponding power converter to optimize and regulate the resultant bus voltage to a point which reduces overall system losses, maintains a low loss condition, and removes series-string non-idealities when the panels are series connected. The controller may also adapt to output condition constraints. Instead of single-port regulation, a combination of input voltage and output voltage management and regulation may be performed within the converter. The source voltage and current characteristic may be shaped to correspond to an optimized power curve at the desired bus voltage to allow MPPT tracking according to the DC voltage bus.

Abstract: A converter unit to improve the response dynamics and overall recovered power in a photovoltaic array configuration. Each photovoltaic panel in the photovoltaic array may be coupled to a respective converter unit, which may include a controller to sense an output voltage and output current produced by the solar panel, and control operation of a power converter to output modified voltage and current corresponding to the solar panel onto a bus coupling the converter units. The controller may operate as an analog or (digital) firmware control system to regulate the input voltage of each power converter unit under indirect guidance of a Maximum Power Point Tracking (MPPT) controller to optimize and regulate the resultant power, and achieve very fast dynamic response to environmental transients.

Abstract: A method of synchronizing a clock signal to a data signal, comprising the steps of (A) detecting a first edge of the data signal and a position of the first edge, (B) determining if the position is within a zone, (C) if the edge is not within the zone, adjusting the clock signal towards the position of the edge, (D) detecting a second edge of the data signal and a position of the second edge, (E) determining a in value indicating a position of the second edge, (F) adding the first value to a second value, wherein the second value indicates a position of a third edge of the data signal and (G) adjusting the clock signal based on the result of step (F).

Abstract: A method of synchronizing a clock signal to a data signal, comprising the steps of (A) detecting a first edge of the data signal, (B) determining a first value indicating a position of the first edge, (C) adding the first value to a second value, wherein the second value indicates a position of a second edge of the data signal and (D) adjusting the clock signal, based on the result of step (C), if the result is greater than a predetermined value.

Abstract: An apparatus comprising a first circuit and a second circuit. The first circuit may be configured to generate (i) a first reference signal in response to a pump-up signal and (ii) a second reference signal in response to a pump-down signal. The second circuit may be configured to generate (a) a first control signal in response to (i) the pump-up signal and (ii) the second reference signal and (b) a second control signal in response to (i) the pump-down signal and (ii) the first reference signal.

Abstract: A deserializer within, for example, a transceiver is provided having multiple stages of pipelined demultiplexers. Each demultiplexer within the earlier stages of the pipelined architecture use only three latches. Two latches are dedicated to producing an odd bitstream (or even bitstream) from odd and even bits within the incoming serial bitstream. Another latch is dedicated to producing an even bitstream (or odd bitstream) from even and odd bits of the serial bitstream. Using only three latches within early stages of the pipelined architecture reduces power consumption and overall size of the deserializer. Clocking signal frequencies of subsequent stages are reduced and the clocking signals are delayed in order to align data outputs from the previous stage with transitions of clocking signals forwarded to the respective stages.

Abstract: A method of synchronizing a clock signal to a data signal, comprising the steps of (A) detecting a first edge of the data signal, (B) determining a first value indicating a position of the first edge, (C) adding the first value to a second value, wherein the second value indicates a position of a second edge of the data signal and (D) adjusting the clock signal based on the result of step (C).

Abstract: An apparatus for determining a state of a plurality of clock signals, comprising a circuit configured to store a state of each of said plurality of clock signals upon an edge of a data signal.

Abstract: A circuit and method comprising a charge pump having a first and a second differential element. The charge pump may be configured to generate a first and a second output signal in response to the first and second differential elements. The first differential element may comprise (i) a first unity gain buffer and (ii) a first and a second transistor pair configured to receive a first and second control signal. The second differential element may comprise (i) a second unity gain buffer and (ii) a third and a fourth transistor pair configured to receive the first and second control signals. The first and second unity gain buffers may stabilize the source nodes of each of the transistors pairs.

Abstract: An apparatus for synchronizing a clock signal to a data signal. The apparatus comprises a detector and a control circuit. The detector may be configured to produce a value representing a position of an edge of said data signal based upon a state of said clock signal. The control circuit may be configured to adjust the clock signal based upon the value.