Abstract: A high-Q differential varactor includes reduced inner spacing dimensions between differential fingers.

Abstract: An integrated oscillator circuit (16) with an amplifier circuit (22) and a frequency-selective feedback network comprising a first resonant circuit (18) and a second resonant circuit (20) is proposed. The oscillator circuit is characterized in that the first resonant circuit (18) is connected to the amplifier circuit (22) solely on the output side and is formed as a parallel resonant circuit comprising a first capacitor (24) and a first inductor (26), and the second resonant circuit (20) is connected to the amplifier circuit (22) solely on the input side (36, 38) and is formed as a parallel resonant circuit comprising a second capacitor (32) and a second inductor (34).

Abstract: An integrated circuit arrangement (1; 2; 3; 4) for setting a predefined phase difference (phi_target) between a first high-frequency signal (x1; x1p, x1n) and a second high-frequency signal (x2; x2p, x2n), comprising: e) a chain connection of a plurality (N) of basic circuits (10; 20; 30; 40), whereby each basic circuit has a first transmission line (11; 11p, 11n) for transmitting the first signal (x1; x1p, x1n), a second transmission line (12; 12p, 12n) for transmitting the second signal (x2; x2p, x2n), and a controllable phase-influencing means (13; 23; 33; 43), connected to the first transmission line, for controllably influencing the phase of the first signal, f) a phase difference detector (14; 34), which is connected to the output-side basic circuit and is formed to detect a current phase difference (phi_actual) between the first and second signal, g) a control unit (15; 35), which is connected to the phase difference detector and each controllable phase-influencing means (13; 23; 33; 43) and is formed

Abstract: A coupling element is disclosed for electromagnetic coupling of at least two conductors of a transmission line, wherein the coupling element is arranged between a first conductor and a second conductor of the transmission line and has at least one discrete component. The coupling element can have at least one first branch embodied as a transmission line segment that is associated with the first conductor, and a second branch embodied as a transmission line segment that is associated with the second conductor. The at least one discrete component can thereby be provided for connecting the first branch to the second branch.

Abstract: A monolithically integratable circuit arrangement is provided, which has at least one inductor, formed as a conductor loop, and at least one capacitor, connected to the conductor loop. According to the invention, the circuit arrangement comprises (a) at least one first conductor loop placed in at least one first metallization level and having a first DC terminal for applying a first DC potential, (b) at least one second conductor loop placed in at least one second metallization level and having a second DC terminal for applying a second DC potential, (c) at least one metal-isolator-metal capacitor with a capacitor plate, which is placed in a third metallization level between the first and second metallization level, and (d) at least one metallic connecting means placed between the capacitor plate and the first conductor loop, said means which connects the capacitor plate in an electrically conducting manner to the first conductor loop.

Abstract: An integrated tunable resonance circuit is provided for providing a high-frequency output signal with a frequency dependent on a control signal, comprising a parallel resonance circuit with a first inductive element and an output for providing the high-frequency output signal, a switching unit with a controlled path, and a control terminal for switching between states, whereby the switching unit is designed to exhibit a predominantly capacitive behavior in a first state and a predominantly resistive behavior in a second state, whereby the resonance circuit is designed to drive the control terminal of the switching unit as a function of the control signal. The resonance circuit has a second inductive element which can be mutually coupled to the first inductive element, whereby the controlled path is connected parallel to the second inductive element. The invention relates furthermore to a voltage-controlled oscillator and to an integrated circuit.

Abstract: An integrated resonance circuit is provided for providing a high-frequency output signal, comprising a first output for providing a first high-frequency output signal with a first frequency and a first amplitude, a first inductive unit connected to the first output, and a first capacitive unit connected to the first output. According to the invention, a second output for providing a second high-frequency output signal with a second frequency and a second amplitude is provided, whereby the second frequency matches the first frequency and the second amplitude differs from the first amplitude, and a second inductive unit, connected to the first output and to the second output, and a second capacitive unit, connected to the second output, are provided. The invention relates furthermore to a voltage-controlled oscillator and to an integrated circuit.

Abstract: A high-Q differential varactor includes reduced inner spacing dimensions between differential fingers.

Abstract: An oscillator is provided that includes a first oscillation generating device for generating an oscillation in response to an excitation signal, whereby the first oscillation generating device has a first terminal and a second terminal; a second oscillation generating device for generating an oscillation in response to an excitation signal, whereby the second oscillation generating device has a third terminal and a fourth terminal; an excitation device, which is formed in a first mode to apply an excitation signal between the first and second terminal of the first oscillation generating device, and in the first mode to apply the excitation signal between the third terminal and the fourth terminal of the second oscillation generating device to obtain a first oscillation with a first characteristic value, and in a second mode to apply an excitation signal between the first terminal of the first oscillation generating device and the third terminal of the second oscillation generating device and in the second mod

Abstract: An integrated circuit is disclosed that includes at least one integrated transmission line for the transmission of a high-frequency differential signal with a number of at least two series-connected line arrangements, each of which has a differential input, a differential output, a first trace, connected to a first terminal of the differential input and a first terminal of the differential output, and a second trace, connected to a second terminal of the differential input and a second terminal of the differential output.

Abstract: A monolithic integrated inductor and a method for configuring the monolithic integrated inductor are provided. The monolithic integrated inductor includes a first coil having a first inductance value, at least one second coil connected in parallel to the first coil and having a second inductance value to form a total inductance, and lines to the first coil and to the second coil. The first coil has at least two first loops spaced at a distance with a path width. The second coil has at least two second loops spaced at the distance with the path width. The first loops form a magnetic coupling, and the second loops form a magnetic coupling.

Abstract: An oscillator is provided that includes a plurality of excitation units for providing an excitation signal and a tank as an oscillation generating unit for generating an oscillation signal in response to the excitation signal, whereby the tank has terminals for providing the oscillator signal, whereby each excitation unit has at least one inductor, whereby the tank is coupled magnetically to the at least one inductor of each excitation unit, and whereby the excitation signal can be transmitted between the excitation units and the tank by means of the magnetic coupling.

Abstract: A monolithic integrated circuit arrangement is provided that includes a first circuit component, which is formed as a differentially supplied coil and has at least one conductor loop encompassing an interior region, and at least one additional circuit component. According to an embodiment of the invention, the additional circuit component of the circuit arrangement is disposed in the interior region.

Abstract: An integratable circuit arrangement is provided having a circuit unit, controllable by means of at least one control voltage, to provide a high-frequency output signal dependent on the at least one control voltage. According to the invention, (a) a clocked DC converter is provided, which is formed to provide at least one control voltage, depending on a control signal applied at its clock input, and (b) the circuit arrangement is formed to supply the clock input with a control signal, dependent on the high-frequency output signal.

Abstract: An integrated circuit arrangement (1; 2; 3; 4) for setting a predefined phase difference (phi_target) between a first high-frequency signal (x1; x1p, x1n) and a second high-frequency signal (x2; x2p, x2n), comprising: e) a chain connection of a plurality (N) of basic circuits (10; 20; 30; 40), whereby each basic circuit has a first transmission line (11; 11p, 11n) for transmitting the first signal (x1; x1p, x1n), a second transmission line (12; 12p, 12n) for transmitting the second signal (x2; x2p, x2n), and a controllable phase-influencing means (13; 23; 33; 43), connected to the first transmission line, for controllably influencing the phase of the first signal, f) a phase difference detector (14; 34), which is connected to the output-side basic circuit and is formed to detect a current phase difference (phi_actual) between the first and second signal, g) a control unit (15; 35), which is connected to the phase difference detector and each controllable phase-influencing means (13; 23; 33; 43) and is formed

Abstract: An integrated circuit arrangement and a use of connecting lines is provided. The integrated circuit arrangement has an inductive unit and a circuit component, wherein the inductive unit has a first inductor with a first coil and first connecting lines, wherein the first connecting lines connect the first coil to the circuit component, wherein the inductive unit has at least one second inductor that is connected in parallel to the first inductor and that has a second coil and second connecting lines, wherein the second connecting lines connect the second coil to the circuit component, and wherein the circuit component is arranged between the first coil and the second coil.

Abstract: A monolithically integratable circuit arrangement is provided, which has at least one inductor, formed as a conductor loop, and at least one capacitor, connected to the conductor loop. According to the invention, the circuit arrangement comprises (a) at least one first conductor loop placed in at least one first metallization level and having a first DC terminal for applying a first DC potential, (b) at least one second conductor loop placed in at least one second metallization level and having a second DC terminal for applying a second DC potential, (c) at least one metal-isolator-metal capacitor with a capacitor plate, which is placed in a third metallization level between the first and second metallization level, and (d) at least one metallic connecting means placed between the capacitor plate and the first conductor loop, said means which connects the capacitor plate in an electrically conducting manner to the first conductor loop.

Abstract: An integrated resonance circuit is provided for providing a high-frequency output signal, comprising a first output for providing a first high-frequency output signal with a first frequency and a first amplitude, a first inductive unit connected to the first output, and a first capacitive unit connected to the first output. According to the invention, a second output for providing a second high-frequency output signal with a second frequency and a second amplitude is provided, whereby the second frequency matches the first frequency and the second amplitude differs from the first amplitude, and a second inductive unit, connected to the first output and to the second output, and a second capacitive unit, connected to the second output, are provided. The invention relates furthermore to a voltage-controlled oscillator and to an integrated circuit.

Abstract: An integrated differential oscillator circuit is provided, which has an amplifier circuit with an input and an output, a frequency-selective feedback network with a first inductor and a second inductor, and a DC power supply. The oscillator circuit is distinguished in that the output is transformer-coupled to the input through the first inductor and the second inductor of the feedback network, wherein the output is connected to a first DC voltage through the first inductor and a first DC path, and the input is connected to a second DC voltage of the DC power supply through the second inductor and a second DC path.

Abstract: An integrated tunable resonance circuit is provided for providing a high-frequency output signal with a frequency dependent on a control signal, comprising a parallel resonance circuit with a first inductive element and an output for providing the high-frequency output signal, a switching unit with a controlled path, and a control terminal for switching between states, whereby the switching unit is designed to exhibit a predominantly capacitive behavior in a first state and a predominantly resistive behavior in a second state, whereby the resonance circuit is designed to drive the control terminal of the switching unit as a function of the control signal. According to the invention, the resonance circuit has a second inductive element which can be mutually coupled to the first inductive element, whereby the controlled path is connected parallel to the second inductive element. The invention relates furthermore to a voltage-controlled oscillator and to an integrated circuit.