Abstract: A switching regulator includes a first switch; a second switch coupled between the first switch and ground; an inductor coupled to a common node between the first and second switches; a capacitor coupled between the inductor and ground; a controller receiving a disable signal, and generating first and second control signals respectively for the first and second switches; and a crossing detector comparing an auxiliary voltage at the common node with a negative reference voltage to generate a comparison signal, and generating the disable signal based on the first control signal and the comparison signal. The second control signal switches into an inactive state upon the disable signal indicating a reference-crossing of the auxiliary voltage.

Abstract: A switching regulator includes a first switch; a second switch coupled between the first switch and ground; an inductor coupled to a common node between the first and second switches; a capacitor coupled between the inductor and ground; a controller receiving a disable signal, and generating first and second control signals respectively for the first and second switches; and a crossing detector comparing an auxiliary voltage at the common node with a negative reference voltage to generate a comparison signal, and generating the disable signal based on the first control signal and the comparison signal. The second control signal switches into an inactive state upon the disable signal indicating a reference-crossing of the auxiliary voltage.

Abstract: A regulator for converting a DC input voltage into a DC output voltage includes: a control module generating a predetermined regulated voltage associated with the DC output voltage, and further generating a control signal based on a feedback voltage associated with the DC output voltage; a switching module outputting, in response to the control signal, one of the reference voltage and the regulated voltage as a switching voltage; and a conversion module generating the DC output voltage and the feedback voltage based on the DC input voltage, a reference voltage output from the reference voltage generation module and the switching voltage.

Abstract: A regulator for converting a DC input voltage into a DC output voltage includes: a control module generating a predetermined regulated voltage associated with the DC output voltage, and further generating a control signal based on a feedback voltage associated with the DC output voltage; a switching module outputting, in response to the control signal, one of the reference voltage and the regulated voltage as a switching voltage; and a conversion module generating the DC output voltage and the feedback voltage based on the DC input voltage, a reference voltage output from the reference voltage generation module and the switching voltage.

Abstract: A protective circuit is provided. The protective circuit includes a charging unit, a voltage regulating unit, and a comparing unit. The charging unit receives a rise signal and an over-current signal, and outputs a first reference voltage. The voltage regulating unit receives the first reference voltage and adjusts an output voltage according, to the first reference voltage and a feedback voltage. The comparing unit receives the feedback voltage and compares the feedback voltage with a first threshold voltage to determine whether to output the rise signal to the charging unit.

Abstract: A voltage regulator circuit includes a soft start module, a pulse width modulation (PWM) module, and a voltage regulator module. The soft start module is used to receive a current feedback voltage corresponding to an input current, and compare the current feedback voltage with a comparison voltage, so as to output a switching signal. The PWM module is used to receive a clock signal and the switching signal, and determine a first PWM signal and a second PWM signal outputted by the PWM module is a high voltage level or a low voltage level according to the clock signal and the switching signal. The voltage regulator module is used to receive and adjust an output voltage corresponding to the first PWM signal and the second PWM signal.

Abstract: A protective circuit is provided. The protective circuit includes a charging unit, a voltage regulating unit, and a comparing unit. The charging unit receives a rise signal and an over-current signal, and outputs a first reference voltage. The voltage regulating unit receives the first reference voltage and adjusts an output voltage according, to the first reference voltage and a feedback voltage. The comparing unit receives the feedback voltage and compares the feedback voltage with a first threshold voltage to determine whether to output the rise signal to the charging unit.

Abstract: A voltage regulator circuit includes a soft start module, a pulse width modulation (PWM) module, and a voltage regulator module. The soft start module is used to receive a current feedback voltage corresponding to an input current, and compare the current feedback voltage with a comparison voltage, so as to output a switching signal. The PWM module is used to receive a clock signal and the switching signal, and determine a first PWM signal and a second PWM signal outputted by the PWM module is a high voltage level or a low voltage level according to the clock signal and the switching signal. The voltage regulator module is used to receive and adjust an output voltage corresponding to the first PWM signal and the second PWM signal.

Abstract: A wobble signal generating apparatus of an optical-electronic system. A first operation unit for generating a reference signal in response to a first input signal and a second input signal that are derived from a plurality of light signals reflected from an optical storage medium is provided. The plurality of reflected light signals is used for generating the reference signal even when the optical-electronic system is recording data onto the optical storage medium. A processing unit processes the reference signal to generate the wobble signal.

Abstract: An apparatus and method for controlling an operation of recording data employed in an optical storage system is disclosed. The apparatus has a sampling-and-holding circuit, an operational amplifier, a plurality of gain amplifiers, and a plurality of switches. The apparatus operates under a short-term open mode, a long-term open mode, and a closed-loop mode sequentially in response to control signals and close/open statuses of the switches. A write-control signal is initialized by using a virtual ground effect within the short-term mode. In the long-term mode, the write-control signal is charged to a voltage level suitable for recording data onto a compact disk, while the charged write-control signal is employed to record data on the compact disk within the closed-loop mode.

Abstract: A peripheral device connection current compensation circuit is proposed, which is designed for use in conjunction with a peripheral control interface on a computer platform, for the purpose of responding to an event of an external peripheral device being connected to the peripheral control interface by providing a current compensating function that can help to prevent an electrical current induced by a pull-up resistor in the peripheral device from flowing into the internal circuitry of the peripheral device. This feature can help maintain the slew rate of the connecting circuitry for the peripheral device at the rated value.

Abstract: A peripheral device connection current compensation circuit is proposed, which is designed for use in conjunction with a peripheral control interface on a computer platform, for the purpose of responding to an event of an external peripheral device being connected to the peripheral control interface by providing a current compensating function that can help to prevent an electrical current induced by a pull-up resistor in the peripheral device from flowing into the internal circuitry of the peripheral device. This feature can help maintain the slew rate of the connecting circuitry for the peripheral device at the rated value.

Abstract: A wobble signal generating apparatus of an optical-electronic system. A first operation unit for generating a reference signal in responsive to a first input signal and a second input signal that are derived from a plurality of light signals reflected from an optical storage medium is provided. The plurality of reflected light signals is used for generating the reference signal even when the optical-electronic system is recording data onto the optical storage medium. A processing unit processes the reference signal to generate the wobble signal.

Abstract: An apparatus and method for controlling an operation of recording data employed in an optical storage system is disclosed. The apparatus has a sampling-and-holding circuit, an operational amplifier, a plurality of gain amplifiers, and a plurality of switches. The apparatus operates under a short-term open mode, a long-term open mode, and a closed-loop mode sequentially in response to control signals and close/open statuses of the switches. A write-control signal is initialized by using a virtual ground effect within the short-term mode. In the long-term mode, the write-control signal is charged to a voltage level suitable for recording data onto a compact disk, while the charged write-control signal is employed to record data on the compact disk within the closed-loop mode.