A circuit for driving a transducer in a mid-air haptic system includes a voltage source, a voltage sink, a current source, a trickle capacitor, a storage capacitor, a haptic system transducer, a first switch, a second switch, and a third switch. Using these components, a portion of the charge required for switching a transducer is sourced from the decoupling capacitance. When the switching completes, additional charge is transferred immediately from the power supply back into the decoupling capacitance. This acts to lower the peak current by fully utilizing 100% of a switching waveform for transfer of charge from the power supply to capacitors local to the transducer.

A circuit for driving a transducer in a mid-air haptic system includes a voltage source, a voltage sink, a current source, a trickle capacitor, a storage capacitor, a haptic system transducer, a first switch, a second switch, and a third switch. Using these components, a portion of the charge required for switching a transducer is sourced from the decoupling capacitance. When the switching completes, additional charge is transferred immediately from the power supply back into the decoupling capacitance. This acts to lower the peak current by fully utilizing 100% of a switching waveform for transfer of charge from the power supply to capacitors local to the transducer.

The present disclosure relates to a power supply unit having: an output for outputting an output current and an output voltage; and a protective element having a signal output path, wherein the protective element is connected downstream of the output and designed to maintain the signal output path when the output current exceeds a first amplitude threshold value and to interrupt the signal output path when the output current exceeds a second amplitude threshold value, the second amplitude threshold value being higher than the first amplitude threshold value; wherein the power supply unit is designed to reduce an amplitude of the output voltage and to increase an amplitude of the output current above the second amplitude threshold value, in order to interrupt the signal output path, when the output current exceeds the first amplitude threshold value.

At least one example embodiment provides a system comprising a three-phase direct-current-to-direct-current converter (DC-DC converter) including a three-phase primary converter coupled to a three-phase secondary converter via at least one transformer; and a controller configured to cause the system to, obtain a load curve based on an operational load ratio or percentage of the three-phase DC-DC converter, the load curve associated with at least one phase of the primary converter and the secondary converter, and adjust or maintain a modulation frequency of the at least one phase of the primary converter and the secondary converter consistent with an operation point on the obtained load curve.

At least one example embodiment provides a system comprising a three-phase direct-current-to-direct-current converter (DC-DC converter) including a three-phase primary converter coupled to a three-phase secondary converter via at least one transformer; and a controller configured to cause the system to, obtain a load curve based on an operational load ratio or percentage of the three-phase DC-DC converter, the load curve associated with at least one phase of the primary converter and the secondary converter, and adjust or maintain a modulation frequency of the at least one phase of the primary converter and the secondary converter consistent with an operation point on the obtained load curve.

Methods and apparatus are provided for a high current control strategy and a low current control strategy using fixed threshold values and variable threshold values. An electrical quantity related to an electrical current which is to be switched is received on an input. The electrical quantity related to the electrical current is compared with a predefined first fixed threshold value in a first comparator for determining a first logical state. The electrical quantity is compared with a first variable threshold value in a second comparator for determining a second logical state. The electrical current is switched between an ON state and an OFF state in response to a switching signal on an output terminal when the electrical quantity of the electrical current meets the first variable threshold value. The first logical state, the second logical state and the switching signal provided at the output terminal vary the first variable threshold value.

Methods and apparatus are provided for a high current control strategy and a low current control strategy using fixed threshold values and variable threshold values. An electrical quantity related to an electrical current which is to be switched is received on an input. The electrical quantity related to the electrical current is compared with a predefined first fixed threshold value in a first comparator for determining a first logical state. The electrical quantity is compared with a first variable threshold value in a second comparator for determining a second logical state. The electrical current is switched between an ON state and an OFF state in response to a switching signal on an output terminal when the electrical quantity of the electrical current meets the first variable threshold value. The first logical state, the second logical state and the switching signal provided at the output terminal vary the first variable threshold value.

A network cooperation-based low power type charged broadcasting set-top box and a controlling method therefor, the set-top box sub-dividing a standby mode of the set-top box into an active standby mode, in which only background functions are processed without processing a main function, and a passive standby mode, in which no functions are processed; extending the passive standby mode occupation time to more than that of the active standby mode; and including a way of transitioning between operating modes by exchanging information regarding the set-top box through an inter-cooperation between a charged broadcasting network and the set-top box, thereby reducing the power consumption of a processor (SoC) which processes multimedia contents and minimizing the power consumption while the set-top box is in standby mode.

A network cooperation-based low power type charged broadcasting set-top box and a controlling method therefor, the set-top box sub-dividing a standby mode of the set-top box into an active standby mode, in which only background functions are processed without processing a main function, and a passive standby mode, in which no functions are processed; extending the passive standby mode occupation time to more than that of the active standby mode; and including a way of transitioning between operating modes by exchanging information regarding the set-top box through an inter-cooperation between a charged broadcasting network and the set-top box, thereby reducing the power consumption of a processor (SoC) which processes multimedia contents and minimizing the power consumption while the set-top box is in standby mode.

Methods and apparatus are provided for a high current control strategy and a low current control strategy using fixed threshold values and variable threshold values. An electrical quantity related to an electrical current which is to be switched is received on an input. The electrical quantity related to the electrical current is compared with a predefined first fixed threshold value in a first comparator for determining a first logical state. The electrical quantity is compared with a first variable threshold value in a second comparator for determining a second logical state. The electrical current is switched between an ON state and an OFF state in response to a switching signal on an output terminal when the electrical quantity of the electrical current meets the first variable threshold value. The first logical state, the second logical state and the switching signal provided at the output terminal vary the first variable threshold value.