An electromechanical amplifying method including a transducing an electrical signal to a mechanical resonator having a mechanical resonance mode with an angular frequency .sub.0; transducing the non-linear oscillations of the resonator into a transduced electrical signal; and filtering the transduced electrical signal to obtain an output signal, the signal transduced to the resonator being obtained by adding a first input signal of a first amplitude and a first angular frequency .sub.s and a second pump signal of a second amplitude greater than the first amplitude and of a second angular frequency .sub.s that is different from the first angular frequency, the first and second angular frequencies being close to the angular frequency .sub.0 of the mechanical resonator and the second pump signal being chosen from a range of angular frequencies .sub.p and amplitudes in which the resonator is actuated in a non-linear regime.

A force detection sensor includes a base member having a first surface subjected to an external force and a second surface having a normal direction different from the first surface, and electrode fingers placed on the second surface, wherein an arrangement direction of the electrode fingers is different from the normal direction of the first surface in a plan view of the second surface. Further, the second surface includes a surface of a piezoelectric material. A constituent material of the piezoelectric material is quartz crystal. The first surface crosses an electrical axis of the quartz crystal.

Gas supply device, comprising a frame equipped with a base and accommodating a plurality of pressurised fluid cylinders connected to a fluidic circuit comprising a first connection end connected to the cylinders and a second end comprising at least one fluidic connection intended to be connected removably to an extraction or filling element for the cylinders, the frame comprising on one of its faces at least one opening giving access to at least one connection of the circuit, the frame also comprising at least one attachment element provided to cooperate with a lifting device.

Gas supply device, comprising a frame equipped with a base and accommodating a plurality of pressurised fluid cylinders connected to a fluidic circuit comprising a first connection end connected to the cylinders and a second end comprising at least one fluidic connection intended to be connected removably to an extraction or filling element for the cylinders, the frame comprising on one of its faces at least one opening giving access to at least one connection of the circuit, the frame also comprising at least one attachment element provided to cooperate with a lifting device.

A measurement probe system is provided that includes a housing, a Quartz Crystal Microbalance (QCM) mass sensor in the housing, a first cover and a second cover attached to the ends of the housing. A chamber is defined between the housing, the mass sensor, and the second cover. An electrical input in electrical communication with the mass sensor and an electrical output in electrical communication with the second cover are also included. The measurement probe system is used to detect nanoparticle levels in an ionic solution includes inputting an ionic solution sample into the chamber, applying a frequency from a signal generator to the QCM via the electrical input, detecting frequency noises with the second cover and transmitting those frequency noises to a frequency counter via the electrical output, and assessing the level of nanoparticles present in the sample based on the frequency measured by the frequency counter.

A method for obtaining the absorption position, mass and rigidity of a particle deposited on the surface of a resonator based on the relative change in the resonance frequency of said resonator in 3 or 4 flexural vibration modes. The rigidity of the particles is of great interest in the study of cells and other biological compounds that change state without significantly changing the mass.

A method for obtaining the absorption position, mass and rigidity of a particle deposited on the surface of a resonator based on the relative change in the resonance frequency of said resonator in 3 or 4 flexural vibration modes. The rigidity of the particles is of great interest in the study of cells and other biological compounds that change state without significantly changing the mass.

A method for monitoring the mass of an object may include (i) applying a vibratory force to the object so that the object vibrates in whole or in part, (ii) providing a sensor or sensors configured to measure vibrations of the object in response to the force, (iii) measuring vibration data from the sensor or sensors, and (iv) comparing the vibration data or a parameter derived therefrom to reference data or one or more reference parameters, so as to determine the mass of the object or an indication that the mass of the object differs from that indicated by the reference data or one or more reference parameters. The object may, but need not necessarily, be a vehicle. The vibratory force may be provided by an integral vehicle component, for example a vehicle engine.

A method for monitoring the mass of an object may include (i) applying a vibratory force to the object so that the object vibrates in whole or in part, (ii) providing a sensor or sensors configured to measure vibrations of the object in response to the force, (iii) measuring vibration data from the sensor or sensors, and (iv) comparing the vibration data or a parameter derived therefrom to reference data or one or more reference parameters, so as to determine the mass of the object or an indication that the mass of the object differs from that indicated by the reference data or one or more reference parameters. The object may, but need not necessarily, be a vehicle. The vibratory force may be provided by an integral vehicle component, for example a vehicle engine.

A sensing sensor includes a main body portion, a piezoelectric resonator, a connecting terminal, and an information storage. The main body portion includes a supply region to which the sample solution is supplied. The piezoelectric resonator is disposed to face the supply region and includes a capturing layer that captures a sensing object. The connecting terminal is configured to attachably/detachably connect a conductive path connected to an electrode of the piezoelectric resonator to a frequency measuring unit. The information storage stores calibration curve information to specify a calibration curve that indicates a relationship between a density of the sensing object and a frequency variation amount of the piezoelectric resonator before and after supplying the sample solution.