Abstract: A pulse width modulator PWM circuit and a corresponding method are presented. The PWM circuit receives a control signal and a clock signal. The PWM circuit generates an output signal based on the control signal and the clock signal. The output signal has a first or second signal value. The PWM circuit has a delay circuit to generate, by delaying the clock signal by a delay period, a first enable signal for setting the output signal to the first signal value. The PWM circuit has a ramp generator to generate a ramp signal based on the clock signal. The PWM circuit has a comparator to generate, by comparing the control signal with the ramp signal, a second enable signal for setting the output signal to the second signal value. By delaying the clock signal by the delay period, a minimum on-time of the output signal may be reduced.

Abstract: A solution is provided for adaptive slope compensation in a DC-DC switching converter. Jitter is reduced for on times less than 50% Tpd by using two or more different slopes for the compensation ramp. Additionally, any discontinuities at the 50% duty cycle point are reduced. Details of the compensation ramp are described, where the ramp rate for the first half of the switching period, for on times greater than 50% Tpd, decreases with increasing on time until, at an on time of 100% Tpd, it is approximately zero. In addition, the ramp rate for the second half of the switching period, for on times greater than 50% Tpd, decreases with decreasing on time until, at a duty of 50%, it is equal to the ramp rate used for the first half of the switching period.

Abstract: The present document describes a power converter configured to provide energy at an output based on energy provided at an input. The power converter comprises a first switch, wherein a first node is coupled to the input and wherein a second node is coupled to an intermediate point, a second switch, wherein a first node is coupled to the intermediate point and wherein a second node is coupled to an inductor point, a capacitor, wherein a first node of the capacitor is coupled to the intermediate point, a first diode element, wherein a first node is coupled to a second node of the capacitor and wherein a second node is coupled to the inductor point, a second diode element, wherein a first node is coupled to a reference port, and wherein a second node is coupled to the second node of the capacitor; and an inductor, wherein a first node is coupled to the inductor point and wherein a second node is coupled to the output.

Abstract: The present document relates to power converters. A power converter has a first stage coupled between an input of the power converter and an intermediate node, and a second stage coupled between the intermediate node and an output of the power converter. The first stage has a capacitive voltage divider with a first flying capacitor, and the second stage has a second flying capacitor and an inductor. On the one hand, the power converter establishes, in a magnetizing state, a magnetizing current path in the second stage from the intermediate node via the inductor to the output of the power converter. On the other hand, the power converter establishes, in a capacitive state, a parallel current path in the second stage from the intermediate node via the second flying capacitor to the output of the power converter.

Abstract: A power converter includes a network of switches having a first capacitor switch coupled to a first flying-capacitor, a first switch to couple a second flying-capacitor to a first port, an inductor coupled to a ground switch. A driver drives the network of switches in two states. In the first state the ground port is coupled to a second port via a first path comprising the first flying-capacitor and the inductor, and the first port is coupled to the second port via a second path comprising the first switch, the second flying-capacitor and the inductor. In the second state the ground is coupled to the second port via a third path comprising the ground switch and the inductor, and one of the first port and the ground port is coupled to the second port via a fourth path comprising the first flying-capacitor while bypassing the inductor.

Abstract: A method of managing power and a power management circuit operable in a plurality of modes are presented. The power management circuit includes a three terminals switching converter coupled to a controller. The switching converter has a single inductor, two sets of switches, a bypass switch and a transition switch. The first set of switches is coupled to an input terminal. The second set of switches is coupled to a battery terminal. The bypass switch is coupled between the battery terminal and a load terminal. The single inductor is provided between a first switching node and a second switching node. The transition switch is provided between the first switching node and the battery or the load terminal. A controller is configured to select a mode of operation by changing a state of at least one of the bypass switch and the transition switch.

Abstract: A method for controlling crosstalk between multiple noise generating wiring tracks and a quiet wiring track by determining a parallel common run length and determining the number of threshold lengths into which the maximum parallel common run length is divided. The space between the quiet wiring track and each wiring track of the noise generating wiring tracks is determined. Multiple metal wiring track structures on one metal wiring level of and multiple metal wiring track structures on another metal wiring level of an integrated circuit that are formed as segments that have various distances between the metal wiring track structures of one wiring level and multiple metal wiring track structures of the other wiring level to form a stair-step or ladder structure that controls individually the spacing applied between multiple active noise wiring track structures and one quiet wiring track structure.

Abstract: The present document describes a control unit for a converter circuit comprising a plurality of converter blocks, wherein each converter block comprises one or more switches which are turned on or off during switching events, and wherein at least some of the converter blocks share a common supply rail. The control unit is configured to determine that a first converter block from the plurality of converter blocks requests a switching event at a first time instant. Furthermore, the control unit is configured to determine whether a second converter block from the plurality of converter blocks, with which the first converter block shares a common supply rail, has a reserved switching time slot for a switching event at the first time instant.

Abstract: An ESD protection circuit is provided. An embodiment provides an ESD protection circuit of a crystal oscillator for bearing an output swing level in an ESD IO for improving a reference clock isolation by adding a stacked diode to the ESD protection circuit and for improving a protection function by applying a secondary diode structure.

Abstract: A lighting system and a method are provided with an adaptive power balancing scheme which reduces or eliminates flicker by sensing the operation of a lamp that is connected to an electronic transformer and adaptively controlling the drive circuit of the lamp to prevent unexpected reset of the electronic transformer. There is provided a lamp with a light source and a drive circuit for the light source; said drive circuit has a power stage for regulating a voltage supplied to the light source, an energy storage device, and control means arranged to selectively disable the power stage. Power is provided to the light source by the energy storage device when the power stage is disabled.

Abstract: A flyback converter is disclosed that includes an auxiliary switch controller that adaptively controls the auxiliary switch for improved zero voltage switching. The auxiliary switch control adaptively adjusts the auxiliary switch on-time period responsive to a transformer reset time for the flyback converter, a resonant oscillation period for a power switch terminal voltage for a power switch transistor, and an on-time period for the power switch transistor to provide the improved zero voltage switching.

Abstract: A driving circuit and a method for a backlight using light-emitting diodes, LED, the backlight having a first and second segment is presented. A driving circuit for an LED backlight with a first and second segment has a first terminal, a second terminal for sensing a first signal, a third terminal for connecting to a first current generating unit for providing a first driving current, a first current regulation circuit, a fourth terminal for sensing a second signal, a fifth terminal for connecting to a second current generating unit, a second current regulation circuit for controlling the second current generating unit, and a control unit which is prepared to adjust the supply voltage and to adjust the first and/or second driving current in dependence on the first and the second signal by means of the first and/or the second current regulation circuits.

Abstract: A sensor data transmitting apparatus that transmits sensor data with low power and a method therefor are provided. According to an embodiment of the disclosure, a sensor data transmitting apparatus that transmits sensor data includes: a wireless communicator configured to access a network through an access point (AP); a timer module configured to generate a wake-up signal in a predetermined cycle; a storage configured to include a non-volatile memory and a volatile memory, a small booting code and a full booting code being recorded in the non-volatile memory and the volatile memory being capable of recording the sensor data; and a processor configured to execute the small booting code or the full booting code, collect the sensor data from a sensor after executing the small booting code, and transmit the sensor data to the AP.

Abstract: The present document relates to Single Inductor Dual Input (SIDI) buck power converters. More specifically, a dual input power converter may comprise an inductor, a first high-side switching element, a second high-side switching element, and a low-side switching element. The inductor may be coupled between an intermediate node and an output of the dual input power converter. The first high-side switching element may be coupled between a first input of the dual input power converter and the intermediate node. The second high-side switching element may be coupled between a second input of the dual input power converter and the intermediate node. The low-side switching element may be coupled between the intermediate node and a reference potential.

Abstract: A method of automated feedforward filter design comprising designing a feedforward filter for a system implementing active noise cancelling is described. The method includes designing the feedforward filter by determining a filter transfer function of the feedforward filter. Optionally, the filter transfer function is determined using a least square method. The method also includes determining the filter transfer function by defining a target transfer function of the feedforward filter and applying the least square method using the target transfer function to determine a filter expression for the filter transfer function. Optionally, the least square method is a weighted least square method.

Abstract: A transceiver having an antenna-connection port and an FEM-connection port is disclosed. Exemplary embodiments provide a transceiver having an antenna-connection port and an FEM-connection port that may support a connection to an external FEM and also support a connection to an antenna without a separate RF switch when an antenna is used without an FEM.

Abstract: A flyback converter is provided that compares a drain-to-source voltage of a synchronous rectifier switch transistor to a negative threshold voltage to detect whether the synchronous rectifier switch transistor has a partially-open or an open fault condition. The flyback converter also compares a gate terminal voltage of a gate driver to the synchronous rectifier switch transistor to a positive threshold voltage to detect whether the synchronous rectifier switch transistor has a gate open or a gate short-circuit fault condition.

Abstract: There is presented a current driver and a corresponding method for driving a current-controlled component such as a semiconductor light source with a driving current. The current driver includes a current regulator for regulating the driving current, a power circuit, and an input stage. The input stage receives a first signal and a second signal and is operable in two phases. In the first phase, the first signal is used to power the power circuit, and in the second phase, the second signal is used to power the power circuit. The current driver may be implemented in an array of cells in which each cell includes a current driver coupled to a current controlled component. The array of cells may be a part of a display device.

Abstract: The present document relates to power converters with multiple feedback loops. The present document relates to a power converter with at least two feedback loops. The power converter may comprise a first error amplifier and a first capacitive element. The power converter may comprise a second error amplifier and a second capacitive element, wherein the second error amplifier is configured to generate, based on a second reference value and a second feedback signal, a second error current for charging the second capacitive element. The power converter may comprise a selector circuit configured to generate a selection signal by comparing a first voltage of the first capacitive element and a second voltage of the second capacitive element. The power converter may comprise a first track amplifier circuit configured to establish an additional current path from a supply rail to the first capacitive element for accelerated charging of said first capacitive element.

Abstract: A dual stage power converter and a method for charging an energy storage device are presented. The dual stage power converter has a first stage and a second stage arranged in series. A first stage has a voltage divider circuit with a flying capacitor to convert an input voltage at an input of the dual stage power converter into a smaller, intermediate voltage at an intermediate node of the dual stage power converter. A second stage has a voltage regulator circuit to receive said intermediate voltage for regulating, using a feedback loop, an output voltage at an output of the dual stage power converter. The described dual stage power converter enables a reduction of the switching power losses in the voltage regulator circuit and a reduction of the resistive power losses within an external cable connecting the dual stage power converter with an external wall adapter.