A method of characterizing frequency fluctuations of a resonator comprising the steps of: a) driving the resonator, in a linear regime, by simultaneously applying two periodical driving signals having respective frequencies, the frequencies being different from each other and from a resonant frequency of the resonator, but contained within a resonance linewidth thereof; b) performing simultaneous measurements of response signal of the resonator at the frequencies of the periodical driving signal; and c) computing a value representative of a correlation between the measurements, the value being indicative of frequency fluctuations of the resonator. An apparatus for implementing such a method is provided.

There is provided a method, including obtaining information indicating at least one reference characteristic; obtaining input data, the input data relating to the output of the tunable filter; determining, based on the input data, at least one characteristic of the tunable filter; upon detecting that the at least one determined characteristic does not match with the at least one reference characteristic, determining tuning instructions for the tunable filter; and applying the tuning instructions in adjusting the tunable filter.

There is provided a method, including obtaining information indicating at least one reference characteristic; obtaining input data, the input data relating to the output of the tunable filter; determining, based on the input data, at least one characteristic of the tunable filter; upon detecting that the at least one determined characteristic does not match with the at least one reference characteristic, determining tuning instructions for the tunable filter; and applying the tuning instructions in adjusting the tunable filter.

A calibration method, a calibration apparatus, and a program capable of estimating a degree of signal loss of an input signal supplied to an oscillator are provided. The calibration method includes: outputting an input signal to be input to an oscillator to be calibrated that includes a resonator and performs parametric oscillation, from a signal generator connected to the resonator via a transmission path while sweeping a frequency or a power of this input signal; acquiring distribution data of an intensity of a reflection signal based on measurement of the intensity of the reflection signal from the oscillator in response to the input signal; and estimating a degree of signal loss by comparing the distribution data acquired by the measurement with the distribution data theoretically obtained in which a value of the degree of the signal loss of the transmission path is assumed.

A local coil matrix for a magnetic resonance tomograph and a magnetic resonance tomograph with a local coil matrix are provided. The local coil matrix has a first coil with two detachable coil segments. The two coil segments have electrical connecting elements. The electrical connecting elements are configured to produce an electrical connection between the coil segments in different relative positions of the two coil segments to each other.

A local coil matrix for a magnetic resonance tomograph and a magnetic resonance tomograph with a local coil matrix are provided. The local coil matrix has a first coil with two detachable coil segments. The two coil segments have electrical connecting elements. The electrical connecting elements are configured to produce an electrical connection between the coil segments in different relative positions of the two coil segments to each other.

Devices and methods for auto-tuning a tunable circuit based on a frequency of operation of the tunable circuit using a clocked frequency detector circuit are described. The clocked frequency detector uses a readily available clock signal to drive a counter circuit to provide an indication of the frequency of operation of the tunable circuit. The tunable circuit, including the clocked frequency detector, can be integrated within a same chip that is autonomously configurable based on the frequency of operation and the readily available clock.

Devices and methods for auto-tuning a tunable circuit based on a frequency of operation of the tunable circuit using a clocked frequency detector circuit are described. The clocked frequency detector uses a readily available clock signal to drive a counter circuit to provide an indication of the frequency of operation of the tunable circuit. The tunable circuit, including the clocked frequency detector, can be integrated within a same chip that is autonomously configurable based on the frequency of operation and the readily available clock.

A method of characterizing frequency fluctuations of a resonator comprising the steps of: a) driving the resonator, in a linear regime, by simultaneously applying two periodical driving signals having respective frequencies, the frequencies being different from each other and from a resonant frequency of the resonator, but contained within a resonance linewidth thereof; b) performing simultaneous measurements of response signal of the resonator at the frequencies of the periodical driving signal; and c) computing a value representative of a correlation between the measurements, the value being indicative of frequency fluctuations of the resonator. An apparatus for implementing such a method is provided.

A method of characterizing frequency fluctuations of a resonator comprising the steps of: a) driving the resonator, in a linear regime, by simultaneously applying two periodical driving signals having respective frequencies, the frequencies being different from each other and from a resonant frequency of the resonator, but contained within a resonance linewidth thereof; b) performing simultaneous measurements of response signal of the resonator at the frequencies of the periodical driving signal; and c) computing a value representative of a correlation between the measurements, the value being indicative of frequency fluctuations of the resonator. An apparatus for implementing such a method is provided.