The device includes at least the following components: a heating resistor intended for heating a component to be regenerated; a current source; a thermistor connected to the current source and thermally coupled to the heating resistor, the thermistor, through which the current flows, having a voltage Vtemp across its terminals, which voltage reflects the temperature of the heating resistor; an error amplifier, which amplifies the difference between the voltage Vset and the voltage Vtemp and delivers a voltage Vctrl that corresponds to the amplified difference; a switch, which switches the current flowing through the heating resistor; an oscillator, which delivers a voltage Vosc formed with a modulated duty cycle, the duty cycle of the pulses of the voltage Vosc being dependent on the voltage Vctrl, the pulses controlling the opening of the switch.

The specification discloses a flashing lamp circuit including (1) at least one LED, (2) a dual-BJT astable multivibrator, and (3) a BJT/MOSFET pair that functions as both (a) a switch between the multivibrator and the lamp and (b) a current regulator for the at least one LED.

The specification discloses a flashing lamp circuit including (1) at least one LED, (2) a dual-BJT astable multivibrator, and (3) a BJT/MOSFET pair that functions as both (a) a switch between the multivibrator and the lamp and (b) a current regulator for the at least one LED.

The device includes at least the following components: a heating resistor intended for heating a component to be regenerated; a current source; a thermistor connected to the current source and thermally coupled to the heating resistor, the thermistor, through which the current flows, having a voltage Vtemp across its terminals, which voltage reflects the temperature of the heating resistor; an error amplifier, which amplifies the difference between the voltage Vset and the voltage Vtemp and delivers a voltage Vctrl that corresponds to the amplified difference; a switch, which switches the current flowing through the heating resistor; an oscillator, which delivers a voltage Vosc formed with a modulated duty cycle, the duty cycle of the pulses of the voltage Vosc being dependent on the voltage Vctrl, the pulses controlling the opening of the switch.

The present invention provides a voltage multiplier system for an electrical device. The system includes a multi-vibrator adapted to generate a clock signal, and a voltage-multiplier module. Further, the multi-vibrator includes a pair of transistors, and at least one resistor-capacitor module. Further, the at least one resistor-capacitor module is connected between the emitter terminal and a base terminal of each of the pair of transistors to limit voltage between the base terminal and the emitter terminal of each of the pair of transistors. The voltage-multiplier module is adapted to boost an input voltage based on the clock signal received from the multi-vibrator.

An oscillator circuit may include a multivibrator for generating an oscillator signal, a supply circuit having a first, second and third current path, and a current mirror for mirroring a current through the second current path into the first current path, the third current path and a current path of the multivibrator. A first transistor in the first current path is operated in weak inversion and saturation on the basis of a first gate voltage. A second transistor in the second current path may be operated in weak inversion and saturation on the basis of the first gate voltage. A third transistor in the second current path may be operated in strong inversion and in the linear region on the basis of a second gate voltage. A fourth transistor in the third current path may be operated in strong inversion and in saturation on the basis of the second gate voltage.

In an oscillator circuit, provision is made of a multivibrator for generating an oscillator signal. Furthermore, provision is made of a supply circuit (100) having a first current path (101), a second current path (102) and a third current path (103). A current mirror (111, 112, 113, 114, 115, 116) serves for mirroring a current (Iptat) through the second current path (102) into the first current path (101), the third current path (103) and at least one current path (104; 105; 106) of the multivibrator (10). A first field effect transistor (121) in the first current path (101) is operated in weak inversion and saturation on the basis of a first gate voltage (Vngate). A second field effect transistor (122) in the second current path (102) is dimensioned in a manner deviating from the first field effect transistor (121) and is operated in weak inversion and saturation on the basis of the first gate voltage (Vngate). A third field effect transistor (130) in the second current path (102) is operated in strong inversion and in the linear region on the basis of a second gate voltage (Vb). A fourth field effect transistor (140) in the third current path (103) is operated in strong inversion and in saturation on the basis of the second gate voltage (Vb).