A voltage controlled oscillator comprises a negative resistance, a first inductor, a fixed capacitor, and a frequency control component. The frequency control component comprises at least one varactor and at least a second inductor connected in series with the at least one varactor. A magnitude of an inductance of the second inductor is selected such that the frequency control component has an effective capacitance range larger than a capacitance range of the at least one varactor.

The disclosure provided a tuner circuit having a zero power loop through (ZPLT) circuit that is capable of providing a loop through path even when no power is being supplied or without a standalone power supply. The tuner circuit includes an input terminal, an output terminal, a ZPLT circuit, and an internal resistor. The input terminal receives a radio frequency (RF) signal. The output terminal is connected to a subsequent tuner. The ZPLT is connected between the input terminal and the output terminal. The internal and an external resistor connected between the turner circuit and subsequent tuner form a voltage divider to divide a bias found at the output terminal to enable the ZPLT circuit for providing a loop through path to deliver the RF signal to the output terminal when the tuner circuit is not powered by a standalone power or a low noise amplifier is enabled.

The disclosure provided a tuner circuit having a zero power loop through (ZPLT) circuit that is capable of providing a loop through path even when no power is being supplied or without a standalone power supply. The tuner circuit includes an input terminal, an output terminal, a ZPLT circuit, and an internal resistor. The input terminal receives a radio frequency (RF) signal. The output terminal is connected to a subsequent tuner. The ZPLT is connected between the input terminal and the output terminal. The internal and an external resistor connected between the turner circuit and subsequent tuner form a voltage divider to divide a bias found at the output terminal to enable the ZPLT circuit for providing a loop through path to deliver the RF signal to the output terminal when the tuner circuit is not powered by a standalone power or a low noise amplifier is enabled.

The disclosure provided a tuner circuit having a zero power loop through (ZPLT) circuit that is capable of providing a loop through path even when no power is being supplied or without a standalone power supply. The tuner circuit includes an input terminal, an output terminal, a ZPLT circuit, and an internal resistor. The input terminal receives a radio frequency (RF) signal. The output terminal is connected to a subsequent tuner. The ZPLT is connected between the input terminal and the output terminal. The internal and an external resistor connected between the turner circuit and subsequent tuner form a voltage divider to divide a bias found at the output terminal to enable the ZPLT circuit for providing a loop through path to deliver the RF signal to the output terminal when the tuner circuit is not powered by a standalone power or a low noise amplifier is enabled.

The disclosure provided a tuner circuit having a zero power loop through (ZPLT) circuit that is capable of providing a loop through path even when no power is being supplied or without a standalone power supply. The tuner circuit includes an input terminal, an output terminal, a ZPLT circuit, and an internal resistor. The input terminal receives a radio frequency (RF) signal. The output terminal is connected to a subsequent tuner. The ZPLT is connected between the input terminal and the output terminal. The internal and an external resistor connected between the turner circuit and subsequent tuner form a voltage divider to divide a bias found at the output terminal to enable the ZPLT circuit for providing a loop through path to deliver the RF signal to the output terminal when the tuner circuit is not powered by a standalone power or a low noise amplifier is enabled.

A tunable inductor arrangeable on a chip or substrate comprises a first winding part connected at one end to a first input of the tunable inductor arrangement, a second winding part connected at one end to the other end of the first winding part, a third winding part connected at one end to a second input of the tunable inductor arrangement, a fourth winding part connected at one end to the other end of the third winding part, and a switch arrangement arranged. The switch arrangement tunes the tunable inductor by selectively connecting the first and fourth winding parts in parallel and the second and third winding parts in parallel, with the parallel couplings in series between the first and second inputs, or connecting the first, second, fourth and third winding parts in series between the first and second inputs. Corresponding transceivers, communication devices, methods and computer programs are disclosed.

A tunable inductor arrangeable on a chip or substrate comprises a first winding part connected at one end to a first input of the tunable inductor arrangement, a second winding part connected at one end to the other end of the first winding part, a third winding part connected at one end to a second input of the tunable inductor arrangement, a fourth winding part connected at one end to the other end of the third winding part, and a switch arrangement arranged. The switch arrangement tunes the tunable inductor by selectively connecting the first and fourth winding parts in parallel and the second and third winding parts in parallel, with the parallel couplings in series between the first and second inputs, or connecting the first, second, fourth and third winding parts in series between the first and second inputs. Corresponding transceivers, communication devices, methods and computer programs are disclosed.

A voltage controlled oscillator comprises a negative resistance, a first inductor, a fixed capacitor, and a frequency control component. The frequency control component comprises at least one varactor and at least a second inductor connected in series with the at least one varactor. A magnitude of an inductance of the second inductor is selected such that the frequency control component has an effective capacitance range larger than a capacitance range of the at least one varactor.

A communication apparatus including a first mixer configured to generate an analog output signal (X.sub.OUT) from an analog input signal (X.sub.IN) using a first mixing signal, a second mixer configured to generate an analog output signal (Y.sub.OUT) from an analog input signal (Y.sub.IN) using a second mixing signal, and a local oscillator configured to provide a reference frequency (f.sub.REF), where the first mixer is configured to derive a first sampling frequency (f.sub.S,1) from the f.sub.REF, and where the second mixer is configured to derive a second sampling frequency (f.sub.S,2) from the f.sub.REF.

The present disclosure provides circuit and method embodiments for calibrating a signal of an integrated circuit. A programmable resistive element is coupled in series with a node of the integrated circuit, where at least part of the integrated circuit is formed in at least one front end of line (FEOL) device level. The programmable resistive element is formed in at least one back end of line (BEOL) wiring level, and the programmable resistive element is in a non-volatile resistive state that is variable across a plurality of non-volatile resistive states in response to a program signal applied to the programmable resistive element.