Abstract: A circuit arrangement for controlling at least one light source comprises a photodetector (2), a sampling circuit (6) for selectively sampling a photodetector signal (lin2) generated by the photodetector (2) as a function of a first and a second light source (10, 12), and a control unit (5), which is coupled on the input side to the sampling circuit (6). The circuit arrangement further comprises a first power-supply source (7), which is coupled to the control unit (5) and is designed for controlling at least one parameter of a first light source (12), and at least one second power-supply source (11), which is coupled to the control unit (5) and is designed for controlling at least one parameter of a second light source (12). The circuit arrangement is suitable, for example, for RGB lighting.

Abstract: A circuit arrangement for driving a light source, in particular, a light-emitting diode, comprises a first adjustable current path (1), that connects a terminal (BAT_IN) for a battery to a terminal (CAP_IN) for a capacitor, a second current path (2) that connects the terminal (CAP_IN) for a capacitor to a terminal (LED_OUT) for a light source, and a third adjustable current path (3) that connects the terminal (BAT_IN) for a battery to the terminal (LED_OUT) for a light source. A control unit (CTRL) is provided that has a control input (IN) and is set up to adjust current intensities (I_CHRG, I_CAP, I_DIRECT) on the first, second and third control paths (1, 2, 3), respectively, as a function of control signals (I_in) that can be applied to the control input (IN). A method for operating a light source, in particular, a light-emitting diode, is also proposed.

Abstract: A circuit arrangement (1) comprises a current source (10), a comparator (50) and a control device (90). The current source (10) serves for supplying a light-emitting diode (41). The comparator (50) may be coupled to the light-emitting diode (41) at a first input (51) via a push-button (101). The comparator (50) may be fed with a reference voltage (VREF) at a second terminal (52). The control device (90) selectively puts the current source (10) into a first operational state (A) for polling a push-button position of the push-button (101) or into a second operational state (B) for emitting radiation by means of the light-emitting diode (41).

Abstract: An input circuit arrangement comprises an input, a comparator, and an evaluation circuit. The input is designed for coupling to a first terminal of an impedance and for feeding an input signal. The comparator is connected to the input of the input circuit arrangement and is designed for delivering an activation signal to an output as a function of a comparison of the input signal with an adjustable threshold. Furthermore, the evaluation circuit is connected to the input of the input circuit arrangement and for its activation to the output of the comparator and is designed for evaluating the value of the impedance that can be connected.

Abstract: The invention relates to a circuit arrangement (20) for a piezo transformer (22) comprising a driver circuit (23), to which the piezo transformer (22) can be connected, and a current sensor (21) for the determining an incoming power signal (IM), which is subject to an incoming current (IE) flowing through the piezo transformer (22). The invention further relates to the circuit arrangement (20) of a control unit (24) for providing a control signal (ST), which is subject the incoming power signal (IM); and an oscillator (25) having an oscillator output (43) for emitting an oscillator signal (SO) to a driver signal input (44) of the driver circuit (23) subject to the control signal (ST).

Abstract: In one embodiment, a charging circuit for a charge accumulator comprises a first terminal (A1) for supplying a charging voltage (UC) and for connecting the charge accumulator (SC) connected to a reference potential terminal (10), a second terminal (A2) for providing a load voltage (UD) and for connecting an electrical load (D1), a control assembly (ST) which is coupled to the first and the second terminals (A1, A2) and has a signal output (A3) for providing a first charge state signal (S1) and a test output (TA) for providing at test signal (on), and a current source (I1) that is coupled to the second terminal (A2), wherein the first charge state signal (S1) is provided depending on a value of an additional voltage (U12) between the first and the second terminals (A1, A2) and depending on the test signal (on), and wherein the charging voltage (UC) is supplied depending on the first charge state signal (S1). The invention also relates to a method for charging a charge accumulator.

Abstract: A circuit for converting an alternating voltage into a rectified voltage includes a first transistor having a first terminal, a second terminal, and a control terminal. The first terminal is configured to receive the alternating voltage via an input terminal, and the second terminal is electrically coupled to an output terminal for outputting the rectified voltage. A control circuit includes a first input, a second input, and a first output. The first input is electrically coupled to the first terminal of the first transistor, the second input is electrically coupled to the second terminal of the first transistor, and the first output is coupled to the control terminal of the first transistor. The control circuit is configured to generate a first control signal based on a first voltage at the first input and based on a second voltage at the second input. The conversion circuit also includes a resistive circuit.

Abstract: A voltage converter comprises a first, a second and a third capacitor (11, 12, 13) which are switched in series in at least one operating state, an input (1) for supplying an input voltage (VIN), an output (2) for providing an output voltage (VOUT), and a compensation circuit (5). The input (1) of the voltage converter is coupled to a capacitor from a group comprising the first, the second and the third capacitor (11, 12, 13). The output (2) of the voltage converter is coupled to a capacitor from the group comprising the first, the second and the third capacitor (11, 12, 13). The compensation circuit (5) is coupled to the first, the second and the third capacitor (11, 12, 13) and adapts a first voltage (V1) of the first capacitor (11), a second voltage (V2) of the second capacitor (12) and a third voltage (V3) of the third capacitor (13) to one another.

Abstract: A control circuit for control of light-emitting diodes has a first LED string (50) with at least one LED (51, 52, 53) and a first supply device (1) for supply of current to the first LED string (50). The supply device (1) has a control input (10) for delivery of a first control signal (CTL) and is provided for delivery, as desired, of a first supply current (IV1) or a second supply current (IV2) in dependence on the first control signal (CTL). The first and the second control currents (IV1, IV2) are non-zero.

Abstract: A current source arrangement, in which at least one branch, comprising a current source (1) and means (2) for the connection of an electrical load (3), is provided. A comparator (5) with transistor (7) connected downstream is connected to a voltage tapping node (4) of said branch. The transistor (7) is connected to a common signal line (8), which is in turn connected to a feedback input of a DC voltage regulator (10). The arrangement can be extended with any number of further branches given a common signal line (8). The current source arrangement proposed is suitable in particular for supplying a plurality of LED array segments for illumination applications and displays.

Abstract: In one embodiment, a central unit, particularly for use in a network, has a memory (2) for at least one light pattern (L) that is suitable for running on a terminal device (5), a control logic (3) connected to the memory (2) and a communications interface (4) coupled to the control logic (3) for providing the at least one light pattern (L) for the terminal device (5). In one embodiment, a terminal device, particularly for use in a network, comprises a process control unit (10), a communications interface (11) connected to the process control unit (10) and that is set up for downloading at least one light pattern (L), and a memory (12) coupled to the process control unit (10) for storing the at least one light pattern (L).

Abstract: A current source (10), comprising a bipolar transistor (1) including a control terminal and a controlled path, a first terminal on the controlled path, to which first terminal an electrical load (D1, D2) may be connected, a second terminal on the controlled path, which second terminal may be connected to a reference potential via a resistor (4), a measuring device (2) coupled to the control terminal for measuring a control current on the control terminal, a compensation device (3) coupled to the measuring device (2) and the bipolar transistor (1) in such a manner that the control current of the bipolar transistor (1) is compensated for at the first terminal of the controlled path.

Abstract: A circuit arrangement (1) for driving an electrical load (13) comprises a first and a second terminal (2, 3) for feeding a first and a second control signal (S1, S2), a first output (23), to which an electrical load (13) can be coupled, a current source (9), which is coupled to the first output (23), and a control device (5). The control device is coupled to the first and the second terminal (2, 3) and comprises a programming circuit (6) and a trigger circuit (7), which are each coupled on the output side to a control input of the current source (9).

Abstract: A voltage-converter arrangement comprises an arrangement input (11) for the supply of an input voltage (VIN), an arrangement output (12) for the provision of an output voltage (VOUT), a voltage converter (13) that is coupled on the input side to the arrangement input (11) and on the output side to the arrangement output (12), and a control device (20) with a control output (21). The control output (21) is coupled to the voltage converter (13). A control signal (SW) can be picked up at the control output (21). The control device (20) is designed to switch the frequency (f) of the control signal (SW) between values from a number N of predetermined, discrete frequency values. The voltage converter (13) is designed to convert the input voltage (VIN) into the output voltage (VOUT) as a function of the control signal (SW).

Abstract: A circuit arrangement (10) comprises a circuit terminal (11) for supplying a data signal (DATA) having digital information, a logic circuit (12) that is coupled at an input (22) to the circuit terminal (11) for supplying the digital information, an activation circuit (13), and a voltage regulator (14) that is coupled for activation to an output (18) of the activation circuit (13). The activation circuit (13) comprises an input (16) that is coupled to the circuit terminal (11), a delay element (17) that is coupled to the input (16) of the activation circuit (13), and the output (18), connected to the delay element (17), for emitting an activation signal (SON).

Abstract: A circuit arrangement (10) for driving an electrical load (2) comprises an input (11) for feeding a power-supply voltage (Vs) with an AC component and an output (13) for providing an output signal (Sout) for driving a connectable electrical load (2). The circuit arrangement (10) further comprises a frequency processing circuit (20) for proving a reference frequency (f1) as a function of the AC component, and a demodulator (60) with a first input (61) for feeding the reference frequency (f1), with a second input (62) that is coupled to the input (11) of the circuit arrangement (10), and with an output (63) that is coupled to the output (13) of the circuit arrangement (10).

Abstract: A circuit arrangement (10) comprises a circuit terminal (11) for supplying a data signal (DATA) having digital information, a logic circuit (12) that is coupled at an input (22) to the circuit terminal (11) for supplying the digital information, an activation circuit (13), and a voltage regulator (14) that is coupled for activation to an output (18) of the activation circuit (13). The activation circuit (13) comprises an input (16) that is coupled to the circuit terminal (11), a delay element (17) that is coupled to the input (16) of the activation circuit (13), and the output (18), connected to the delay element (17), for emitting an activation signal (SON).

Abstract: An apparatus includes a voltage converter for supplying voltage to an electrical load. The voltage converter is electrically connected at an output to a terminal of a series circuit. The voltage converter includes mechanisms for connecting the electrical load and a current sink. The voltage supplied by the voltage converter is dependent on an input voltage and on a present multiplication factor. The apparatus also includes a first comparator, a second comparator, and selection logic.

Abstract: A voltage converter comprises a first, a second and a third capacitor (11, 12, 13) which are switched in series in at least one operating state, an input (1) for supplying an input voltage (VIN), an output (2) for providing an output voltage (VOUT), and a compensation circuit (5). The input (1) of the voltage converter is coupled to a capacitor from a group comprising the first, the second and the third capacitor (11, 12, 13). The output (2) of the voltage converter is coupled to a capacitor from the group comprising the first, the second and the third capacitor (11, 12, 13). The compensation circuit (5) is coupled to the first, the second and the third capacitor (11, 12, 13) and adapts a first voltage (V1) of the first capacitor (11), a second voltage (V2) of the second capacitor (12) and a third voltage (V3) of the third capacitor (13) to one another.

Abstract: A control arrangement for a voltage converter includes a first input electrically connected to a device configured to sense a first current in a primary side of a transformer and a first output electrically connected to a control terminal of a transistor. The transistor is electrically connected with the primary side of the transformer and the first output is configured to supply a control signal to the control terminal. The control arrangement also includes a computing unit configured to adjust the control signal so that the transistor has a low resistance value during a switched-on phase and a high resistance value during a switched-off phase.