The invention relates to acoustic transducers that operate in the ultrasound range and in particular to transducers of this type that are capacitive and comprise a vibrating membrane. Description
Ultrasonic waves are pressure waves the frequency range of which starts at 20 kHz and extends up to a few tens of MHz. Ultrasonic waves propagate at a speed that depends on the propagation medium: about 343 m/s in air and 1500 m/s in water. The waves undergo, as they propagate, absorption at a rate that increases with their frequency. Moreover, when the wave encounters a discontinuity in the propagation medium, some of the wave is transmitted and some is reflected.
Various applications use ultrasonic transducers with a view to:
In such applications, there is an increasing need for miniaturized electroacoustic transducers for propagating ultrasound through fluid media. In a fluid, an acoustic wave is generated by the movement of a movable surface. At the movable surface, the acoustic intensity of the source is equal to the impedance of the medium multiplied by the square of the speed of the movable surface. For a given frequency, the larger the amplitude of the movements of the movable surface of the transducer, the greater the intensity of the source.
Vibrating-membrane transducers are being developed for miniaturized applications. Such transducers include membranes that are suspended above cavities that are produced in a carrier or that are open. The diameter of circular cavities is generally comprised between a few tens of and a few hundred microns. The thickness of such membranes is generally larger than 50-100 nm and up to several microns. The resonant frequency of the complete device depends on the geometry of the cavity/membrane assembly and on the materials used.
One particular case of a vibrating-membrane transducer is the capacitive vibrating-membrane transducer. The membrane of an emitter is for example subjected to an electrostatic force by applying an alternating potential difference across this membrane and a conductive electrode housed at the bottom of the cavity. For a detector, the value of the capacitance formed between the membrane and the electrode housed at the bottom of the cavity is determined at any given time by the deformation of the membrane, and therefore by the instantaneous pressure incident on the membrane. Detection involves measuring the variations in this capacitance.
The movement of the membrane is maximum at the resonant frequency of this membrane. Emission intensity is therefore maximum at the resonant frequency of the membrane. The same goes for the detection of a wave: the sensitivity of the sensor is maximum at the resonant frequency of its membrane.
Ultrasonic transducers are therefore generally associated with an optimal operating frequency that is determined by the resonance of their membrane. The quality factor of the mechanical resonator including the membrane determines the passband of the transducer. A bandwidth is conventionally bounded by frequencies corresponding to a decrease of half in the acoustic intensity with respect to resonance, on either side of this resonant frequency. The widest passbands may be of the same order of magnitude as the resonant frequency: for example, a transducer of resonant frequency of 1 MHz with a bandwidth of 600 kHz, i.e. a passband extending from 700 kHz to 1300 kHz, is considered to be a wide-band transducer. Outside of the passband, the amplitudes of vibration may be lower by several orders of magnitude than the amplitudes at resonance.
This resonant operating mode implies that each application requires a specific transducer, because very different ultrasonic frequencies cannot be covered by one and the same transducer: the detection of obstacles is typically carried out at 40 kHz with a range of a few metres in air, the capture of gestures is carried out between 100 kHz and 400 kHz with a range of a few tens of centimetres in air, the detection of fingerprints is carried out between 1 MHz and 10 MHz with a millimetric range in a nonuniform medium, and ultrasonic medical imaging uses frequencies between 5 MHz and 50 MHz in aqueous-type media.
Document WO2012010786 describes a capacitive vibrating-membrane ultrasonic transducer. In this transducer, a cavity of a carrier is kept under vacuum under a membrane. The document suggests making the transducer operate at a frequency below the resonant frequency and considering a wider range of operating frequencies, with the performance level varying depending on the frequency used.
There is therefore a need for transducers having wider frequency bands of use to be designed. Moreover, in range-finding applications, there is a need to minimize the blind spot found in close proximity.
The invention aims to solve one or more of these drawbacks. The invention thus relates to a capacitive vibrating-membrane ultrasonic transducer such as defined in the appended claims.
The invention also relates to the variants in the dependent claims. Those skilled in the art will understand that each of the features of the dependent claims and of the description may be independently combined with the features of an independent claim, without however constituting an intermediate generalization.
Other features and advantages of the invention will become clear from the nonlimiting description that is given thereof below, by way of indication, with reference to the appended drawings, in which:
[
[
[
[
[
[
[
A vibrating membrane 11 is fastened to the carrier 13 and covers the cavity 14. The membrane 11 has an external upper face 113 and an internal lower face 114. The membrane 11 is placed facing the conductive element 101. The membrane 11 and the conductive element 101 are separated by the cavity 14 and the dielectric layer 15.
In the illustrated example, the membrane 11 is fastened to the dielectric layer 132 of the carrier 13 by way of an electrode 102. As detailed below, the electrode 102 is merely an optional component for exciting the membrane 11. The electrode 102 here takes the form of a plate. The electrode 102 is here fastened to an upper face of the dielectric layer 132 and has a similar shape thereto given that it is passed through by the same bore. The electrode 102 makes electrical contact with the membrane 11 on the periphery of the cavity 14.
The conductive element 101 forms an electrode of the transducer 1. An exciting circuit 2 has its terminals connected on the one hand to the electrode 102 and on the other hand to the conductive element 101. By applying an alternating potential across its terminals, the exciting circuit 2 allows an electric field to be created between the membrane 11 and the conductive element 101, this subjecting the membrane 11 to an electrostatic force and causing it to bow. The transducer 1 is therefore capacitive.
In linear regime, the movement d of the centre of the membrane 11 in a direction normal to its plane at rest is proportional to the applied force F and to the shear modulus of the membrane: F=D*d.
For a membrane 11 forming a plate, in the absence of tension:
D=E*h
3/12*(1η2)
with E Young's modulus and η the Poisson's coefficient of the material of the membrane 11 and h its thickness.
In the mechanics of vibrations, theory allows different vibratory behaviours to be distinguished between depending on the geometry and design of the vibrating membrane 11.
To simplify, different one-dimensional objects, such as a beam and a rope, may firstly be analysed. A beam will have a behaviour and a resonant frequency that are mainly determined by its geometry (its length and its cross section) and the 30 Young's modulus of the material from which it is made. The behaviour of a rope, for its part, will be essentially defined by its tension. The tauter the rope, the higher its resonant frequency.
Likewise, for two-dimensional objects, the following are both encountered:
Another resonant frequency fm is associated with this behaviour.
The resonant frequency of the object is the quadratic sum of the resonant frequencies due to each of these two behaviours.
For a circular object of radius R embedded on its periphery, the resonant frequency fr is defined by the relationship:
fr(R)=√(fm2(R)+fP2(R))
The resonant frequency fm in membrane mode may notably be defined in this case by the following relationship, with T the tension of the object (in N/m) and s its density per unit area (in kg/m2):
The resonant frequency fp in plate mode may notably be defined in this case by the following relationship, with p the density of the circular object (in kg/m3):
Those skilled in the art will be able to define, empirically or analytically, the resonant frequencies fp and fm for other vibrating-membrane geometries.
According to one preferred aspect of the invention, the vibrating membrane 11 of the transducer 1 respects the following relationship: fm>fp. Preferably, the vibrating membrane 11 of the transducer 1 respects the following relationship: fm>1.5*fp, and even more preferably fm>2.5*fp. The vibrating membrane 11 of the transducer 1 therefore has a membrane mode that is preponderant with respect to its plate mode. Advantageously, by satisfying this inequality, it is possible to place the membrane in a mode in which it exhibits significant movement far from resonance, i.e. in linear mode.
According to the invention, the exciting circuit 2 is configured to apply, across its terminals, a signal the frequency components of which are included in the frequency interval [0−fo], fo respecting the relationship f0<fr, and preferably fo<0.66*fr (i.e. fr>1.5*fo). Therefore, it may be deduced therefrom that f0<fr<fm. Thus, the membrane 11 is excited at a frequency clearly below its resonant frequency in membrane mode: the movements of the membrane are not caused by a resonance effect, but by a forced-oscillation mechanism, this allowing a wide range of usable excitation frequencies, extending from very low frequencies (a few hertz) up to 0.66*fr, and in which the level of performance remains constant, to be obtained. The same transducer 1 may thus be used for many different applications. Contrary to resonant excitations, the use of forced oscillations also allows short pulses to be generated and, therefore, for range-finding applications for example, blind spot to be minimized. The use of forced oscillations also allows the exciting power to be increased at constant frequency. Advantageously, the exciting circuit 2 is configured to apply, across its terminals, an exciting signal with a maximum frequency fo respecting the relationship fr>f0, and advantageously fr>1.5*fo.
Advantageously, the exciting circuit 2 is configured to apply, across its terminals, a signal such that the ratio between the total electrical power applied across these terminals and the electrical power applied in a frequency range comprised between 0.9*fr and 1.1*fr is at least equal to 10. Thus, most of the exciting power is applied outside of the resonant range.
The graph of
Ultrasonic waves were emitted experimentally between 20 kHz and 140 kHz by membranes of 15 nm thickness suspended above circular cavities of 10 μm diameter.
The components of the transducer 1 may have the following dimensions and compositions:
Advantageously, the membrane 11 has a thickness at most equal to 100 nm. The membrane 11 may advantageously be intended to vibrate in the cavity 14 with an amplitude of at least 5% of the suspended length and lower than the depth of the cavity.
The diameter of the cavity 14 may be decreased in order to increase the resonant frequency of the membrane 11.
A continuous or very low frequency electrostatic force may be applied by the exciting circuit 2 in order to impose an initial mechanical tension on the vibrating membrane 11. The exciting circuit 2 will then apply, across the electrode 102 and the element 101, a potential difference with a continuous or very-low-frequency component (for example of frequency at most equal to 50 Hz) so as, inter alia, to allow the sensitivity and dynamic range of the transducer 1 to be modulated.
The measuring circuit 3 measures the charge movements related to the instantaneous variation in the capacitance between the electrode 102 and the element 101, which variation is induced by the vibrations of the membrane 11.
The measuring circuit 3 will also possibly apply, across the electrode 102 and the element 101, a potential difference with a continuous or very-low-frequency component (for example of frequency at most equal to 50 Hz) so as to be able to modulate the sensitivity and dynamic range of the transducer 1.
It is also possible to envision connecting an exciting circuit 2 and a measuring circuit 3 such as described above to the membrane 11 and conductive element 101. The exciting circuit 2 and the measuring circuit 3 may be connected selectively and independently by respective switches. It will then be possible to independently process the emission and reception of an acoustic signal, for example in order to implement a range-finding mode.
In the various examples, if the membrane 11 includes a conductive layer, it is possible not to interpose an electrode 102 between this membrane 11 and the circuits to which it is connected. In particular, in the following embodiment a membrane 11 including a combination of a conductive layer and of a layer chosen for its mechanical properties is described: the electrode 102 may be omitted if a circuit is directly connected to the conductive layer. This corresponds to the example of
The pressure in the cavities 14 may also be different from the surrounding pressure. A peripheral seal may thus be employed if the various cavities 14 of the matrix array are placed in communication with one another.
In order to be able to orient the emission or reception beam, an array of transducers 1 may comprise a plurality of conductive elements 101 (for example arranged in parallel) and/or a plurality of electrodes 102 (for example in parallel). A plurality of channels may for example be formed. Parallel conductive elements 101 may be positioned perpendicular to the parallel electrodes 102. The elements of the array are thus defined by superposing an electrode 102 and a conductive element 101 and are individually addressable. The pitch between the conductive elements of 101 or 102 may be decreased to the pitch of the array of elementary transducers. A small elementary transducer diameter of 10 μm with a pitch of 15 μm for example allows beamforming to be carried out at up to more than 10 MHz in air.
Number | Date | Country | Kind |
---|---|---|---|
18 74085 | Dec 2018 | FR | national |