Abstract: A communication system is disclosed herein. The communication system includes a master device that includes a master clock and is connected to a host through a communication network, and a plurality of nodes connected to the master device. The master device transmits one or more periodic beams that include a radio frequency. Each of the nodes includes a node clock that is configured and in synchronization with the master clock based on the one or more periodic beams. The communication system establishes a connection for communication between the master device and at least one node when the node clock of the at least one node is in synchronization with the master clock. The communication system further includes at least one repeater 104A operatively connected between the master device and at least one node.

Abstract: In a solar panel array, each solar panel in a series-connected string has a current source connected across its output terminals. The current source generates a programmable output current equal to the difference of the load current drawn from the panel and the current corresponding to the maximum power point (MPP) of the panel. As a result, each of the panels in the string is operated at its MPP. When the array contains multiple strings connected in parallel, a voltage source is additionally connected in series with each string. The voltage sources are programmable to generate corresponding output voltages to enable operation of each panel in each of the multiple strings at its MPP. Respective control blocks providing the current sources and voltage sources automatically determine the MPP of the corresponding panels. In an embodiment, the control blocks are implemented as DC-DC converters in conjunction with measurement and communication units.

Abstract: A communication system is disclosed herein. The communication system includes a master device that includes a master clock and is connected to a host through a communication network, and a plurality of nodes connected to the master device. The master device transmits one or more periodic beams that include a radio frequency. Each of the nodes includes a node clock that is configured and in synchronization with the master clock based on the one or more periodic beams. The communication system establishes a connection for communication between the master device and at least one node when the node clock of the at least one node is in synchronization with the master clock. The communication system further includes at least one repeater 104A operatively connected between the master device and at least one node.

Abstract: In a solar panel array that includes a string of series-connected panels, the load current flowing through the string is measured. The peak current (Ipp) of a panel in the string is determined. A current equal to the difference of the load current and the peak current (Ipp) is generated in a current source connected across the output terminals of the panel. The panel is thereby operated at its maximum power point (MPP). To determine the peak current (Ipp) of the panel, the magnitude of current flowing through the panel is iteratively changed and the corresponding power generated by the panel is computed. The change in the current through the panel and the measurement of the corresponding power are repeated until a maximum power is determined as being generated by the panel. The maximum power corresponds to the maximum power point (MPP) and the peak current (Ipp) of the panel.

Abstract: In a solar panel array, each solar panel in a series-connected string has a current source connected across its output terminals. The current source generates a programmable output current equal to the difference of the load current drawn from the panel and the current corresponding to the maximum power point (MPP) of the panel. As a result, each of the panels in the string is operated at its MPP. When the array contains multiple strings connected in parallel, a voltage source is additionally connected in series with each string. The voltage sources are programmable to generate corresponding output voltages to enable operation of each panel in each of the multiple strings at its MPP. Respective control blocks providing the current sources and voltage sources automatically determine the MPP of the corresponding panels. In an embodiment, the control blocks are implemented as DC-DC converters in conjunction with measurement and communication units.

Abstract: In a solar panel array that includes a string of series-connected panels, the load current flowing through the string is measured. The peak current (Ipp) of a panel in the string is determined. A current equal to the difference of the load current and the peak current (Ipp) is generated in a current source connected across the output terminals of the panel. The panel is thereby operated at its maximum power point (MPP). To determine the peak current (Ipp) of the panel, the magnitude of current flowing through the panel is iteratively changed and the corresponding power generated by the panel is computed. The change in the current through the panel and the measurement of the corresponding power are repeated until a maximum power is determined as being generated by the panel. The maximum power corresponds to the maximum power point (MPP) and the peak current (Ipp) of the panel.

Abstract: Testing of a mixed signal integrated circuit (IC) potentially in the form of a die using a tested/calibrated integrated circuit. In an embodiment, the mixed signal IC generates an analog signal from a symbol, and transmits the analog signal to the calibrated integrated circuit. The calibrated IC determines a valid symbol corresponding to the signal level (e.g., voltage) of the received analog signal, and determines a deviation of the signal level of the received analog signal from the voltage level corresponding to the valid symbol. The deviation is deemed to represent the degree of defect of the mixed signal IC based on the assumption that the calibrated IC operates accurately. The deviation is used to either discard or qualify/accept the mixed signal IC.

Abstract: Testing of a mixed signal integrated circuit (IC) potentially in the form of a die using a tested/calibrated integrated circuit. In an embodiment, the mixed signal IC generates an analog signal from a symbol, and transmits the analog signal to the calibrated integrated circuit. The calibrated IC determines a valid symbol corresponding to the signal level (e.g., voltage) of the received analog signal, and determines a deviation of the signal level of the received analog signal from the voltage level corresponding to the valid symbol. The deviation is deemed to represent the degree of defect of the mixed signal IC based on the assumption that the calibrated IC operates accurately. The deviation is used to either discard or qualify/accept the mixed signal IC.

Abstract: A mixed-signal core designed for efficient concurrent testing analog, mixed-signal, and digital components. One tester may test all components and, thereby, reduce test time without losing full test coverage. An analog module includes all the analog and mixed-signal components of the mixed-signal core, while a first digital module includes digital components required for functional/parametric verification of the mixed-signal components within the analog module. A first virtual boundary connects the analog and the first digital modules to gate the signal transfer during testing. A second digital module includes the remaining digital components of the mixed-signal core, whereby a second virtual boundary separates it from the first digital module. This type of partitioning enables the mixed-signal core to have three modes of operation, using which the analog, mixed-signal and digital components can all be tested.

Abstract: A mixed-signal core disclosed herein is designed for efficient concurrent testing analog, mixed-signal, and digital components. One tester may test all components and, thereby, reduce test time without losing full test coverage. An analog module includes all the analog and mixed-signal components of the mixed-signal core, while a first digital module includes digital components required for functional/parametric verification of the mixed-signal components within the analog module. A first virtual boundary connects the analog and the first digital modules to gate the signal transfer during testing. A second digital module includes the remaining digital components of the mixed-signal core, whereby a second virtual boundary separates it from the first digital module.