WO1993025874A1 - Optical lever acoustic and ultrasound sensor - Google Patents

Optical lever acoustic and ultrasound sensor Download PDF

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Publication number
WO1993025874A1
WO1993025874A1 PCT/US1993/005442 US9305442W WO9325874A1 WO 1993025874 A1 WO1993025874 A1 WO 1993025874A1 US 9305442 W US9305442 W US 9305442W WO 9325874 A1 WO9325874 A1 WO 9325874A1
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WO
WIPO (PCT)
Prior art keywords
hght
reflected
reflective surface
incident
acoustic sensor
Prior art date
Application number
PCT/US1993/005442
Other languages
French (fr)
Inventor
Jon W. Erickson
Original Assignee
Erickson Jon W
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Priority claimed from US07/895,544 external-priority patent/US5249163A/en
Application filed by Erickson Jon W filed Critical Erickson Jon W
Priority to EP93916448A priority Critical patent/EP0598113A1/en
Publication of WO1993025874A1 publication Critical patent/WO1993025874A1/en

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Classifications

    • GPHYSICS
    • G01MEASURING; TESTING
    • G01HMEASUREMENT OF MECHANICAL VIBRATIONS OR ULTRASONIC, SONIC OR INFRASONIC WAVES
    • G01H9/00Measuring mechanical vibrations or ultrasonic, sonic or infrasonic waves by using radiation-sensitive means, e.g. optical means
    • GPHYSICS
    • G01MEASURING; TESTING
    • G01DMEASURING NOT SPECIALLY ADAPTED FOR A SPECIFIC VARIABLE; ARRANGEMENTS FOR MEASURING TWO OR MORE VARIABLES NOT COVERED IN A SINGLE OTHER SUBCLASS; TARIFF METERING APPARATUS; MEASURING OR TESTING NOT OTHERWISE PROVIDED FOR
    • G01D5/00Mechanical means for transferring the output of a sensing member; Means for converting the output of a sensing member to another variable where the form or nature of the sensing member does not constrain the means for converting; Transducers not specially adapted for a specific variable
    • G01D5/26Mechanical means for transferring the output of a sensing member; Means for converting the output of a sensing member to another variable where the form or nature of the sensing member does not constrain the means for converting; Transducers not specially adapted for a specific variable characterised by optical transfer means, i.e. using infrared, visible, or ultraviolet light
    • G01D5/28Mechanical means for transferring the output of a sensing member; Means for converting the output of a sensing member to another variable where the form or nature of the sensing member does not constrain the means for converting; Transducers not specially adapted for a specific variable characterised by optical transfer means, i.e. using infrared, visible, or ultraviolet light with deflection of beams of light, e.g. for direct optical indication
    • G01D5/30Mechanical means for transferring the output of a sensing member; Means for converting the output of a sensing member to another variable where the form or nature of the sensing member does not constrain the means for converting; Transducers not specially adapted for a specific variable characterised by optical transfer means, i.e. using infrared, visible, or ultraviolet light with deflection of beams of light, e.g. for direct optical indication the beams of light being detected by photocells
    • AHUMAN NECESSITIES
    • A61MEDICAL OR VETERINARY SCIENCE; HYGIENE
    • A61BDIAGNOSIS; SURGERY; IDENTIFICATION
    • A61B8/00Diagnosis using ultrasonic, sonic or infrasonic waves
    • A61B8/44Constructional features of the ultrasonic, sonic or infrasonic diagnostic device
    • A61B8/4483Constructional features of the ultrasonic, sonic or infrasonic diagnostic device characterised by features of the ultrasound transducer

Definitions

  • the present invention relates generally to diagnostic medical instrumentation and, more particularly, to ultrasonic transducers used in medical imaging.
  • a primary objective of the present invention is to provide a robust, low-cost compact transducer with greatly increased sensitivity to ultrasound signals.
  • a typical ultrasonic imaging system makes use of one or more piezoelectric transducers which act as the source (actuator) of the ultrasonic beam or signal, and which often also serve to sense the reflected signal (sensor).
  • An electrical pulse generated by an electronic control module is converted to an ultrasonic pulse by the transducer/actuator in the probe.
  • the probe is in contact with the body, and the ultrasonic pulse is transmitted through the probe into the body.
  • the pulse is then absorbed by body tissues or reflected to different degrees from the boundaries between body tissues.
  • the reflections reach the transducer/sensor at different times, which vary with the distance to the tissue boundaries.
  • the reflections also have different energies, due to the different acoustic impedances of the tissues, as well as absorption by the intervening tissues.
  • the transducer/sensor converts the reflections into a weak electrical signal, which contains information that can be processed into an image of the body.
  • a great variety of ultrasonic transducers are presently in use or under development.
  • Shapes and sizes vary widely in order to meet special needs. Focusing by electronic or mechanical means, or some combination thereof, can be used to produce and steer a narrow ultrasonic beam of desired focal length. Likewise, mechanical and electronic focusing can be used to sense the reflections from a particular direction and distance. Phased transducer arrays of various configurations have been employed to achieve particular focusing properties, under electronic control. (The term "phased array” is taken from radar technology, in which the phase relationships of signals from multiple antennae are processed electronically to improve resolution and sensitivity.) The acquired signal is then converted into an image using analog or, depending on cost and technological considerations, digital processing. Good resolution of ultrasound images is important for medical applications.
  • resolution Some limits to resolution are fundamental to the physics of wave propagation (for example, acoustic shadows and reverberations, and geometric artifacts) and are best dealt with by educating the user, or by appropriate image processing algorithms. Other factors affecting resolution involve transducers and electronic instrumentation (such as axial and lateral resolution, and dynamic range) and are susceptible to improvement.
  • Axial resolution can be limited in part by the wavelength of the ultrasonic signal ("ultrasound” simply designates sound waves of a frequency above the audible range, with wavelengths of millimeters or less). Absorption of ultrasonic energy by body tissues tends to restrict the useful depth of field to about 200 wavelengths, due to attenuation of the signal.
  • piezoelectric polymers such as polyvinylideneflouride
  • actuators which produce the ultrasonic pulse
  • sensors which detect the reflected signal.
  • the physics and engineering of piezoelectric sensors are relatively well understood.
  • the sensitivity of a simple piezoelectric sensor, such as a small block of quartz, can be greatly improved by use of a more complicated geometry, the "piezoelectric bimorph" shape.
  • the bimorph has been used since 1930 in microphones and phonograph needle assemblies, but various design considerations such as high cost and fragility preclude its use in ultrasound transducers.
  • optical levers have proven to be effective in routine measurements of extremely small deflections, of less than 0.01 nanometer, in atomic force microscopy (AFM). This measurement strategy can be implemented in robust ultrasound transducers at low cost, with great flexibility in design.
  • AFM atomic force microscopy
  • this patent application presents an acoustic sensor which uses the optical lever principle to amplify ultrasonic signals.
  • the patent application also presents certain improvements to the optical lever acoustic sensor which use an optical amplification means to improve the amplification of the sensor.
  • the signal amplification provided by the basic optical lever acoustic sensor is dependent on the geometry of the optical lever.
  • Even though the optical lever arrangement presented is capable of very high signal amplification, there are practical limitations to the level of amplification possible before the size of the sensor becomes unwieldy.
  • the improvements presented overcome these limitations by using the optical amplification means to amplify acoustic or ultrasonic signals to an even greater degree without significantly increasing the size of the sensor.
  • the primary objective of the present invention is to provide an acoustic and ultrasound sensor which uses the optical lever principle to amplify ultrasonic signals.
  • the optical lever acoustic sensor provides increased sensitivity to acoustic signals and an improved signal-to- noise ratio in a low cost, highly robust transducer.
  • It is a further objective of the present invention is to provide an optical lever acoustic and ultrasound sensor with increased sensitivity to acoustic signals. It is an important part of this objective to provide the desired increase in sensitivity by an optical amplification means which amplifies the motion of an incident acoustic wave and converts it to an electical signal for image processing.
  • An optical amplification means is preferred because it is not subject to the same signal-to-noise limitations as the electronic amplifiers typically used in the prior art.
  • the optical amplification means is also capable of operating in harsh environments with high levels of electromagnetic interference that would render prior art electronic amplifiers ineffective, since they amplify the electronic noise as well as the signal.
  • the present invention proposes the use of an optical lever to detect the ultrasonic reflections.
  • the optical lever makes use of a beam of light shining at an oblique angle on a mirrored surface (e.g., a membrane or piston) in good acoustic contact with the ultrasonic medium.
  • the reflected beam of light is directed onto a position-sensitive detector.
  • Small movements in the mirrored surface result in relatively large changes in the position where the beam of light strikes the detector.
  • the position-sensitive detector is insensitive to fluctuations in the hght intensity, which lowers the overall costs (especially in anrays of such sensors).
  • the size of the sensor and of the transducer as a whole can also be reduced considerably, since all the components can be fabricated with microelectronic techniques.
  • the present invention proposes several improvements to the basic design of the optical lever acoustic sensor which include an optical amplification means for improving the sensitivity of the sensor.
  • an optical amplification means for improving the sensitivity of the sensor.
  • Three different approaches to the optical amplification are disclosed which can be used separately or in combination with one another.
  • the vibrating mirror Ml is made part of a cantilever arrangement that increases the angular deflection of the incident hght beam.
  • the acoustic energy impinging on the large area of the diaphragm is transferred into the small area of the post
  • the post is connected to the cantilevered mirror Ml at a point close to the hinge, in order to increase the angular deflection for a given increment of vertical deflection, and hence the overall sensitivity.
  • a second, stationary mirror M2 is positioned approximately parallel to the vibrating mirror surface.
  • the reflected beam of hght is directed by the stationary mirror M2 back onto the vibrating mirror Ml, and picks up a second increment of information about the acoustic signal with each increment in angular deflection. Even more reflections may be included so as to increase the total number of signal increments, the total signal in the light beam being proportional to the number of times the hght beam has been reflected from the vibrating surface Ml.
  • the effective moment of the optical lever is increased within a small volume by the use of additional stationary mirrors M3 and M4.
  • the stationary mirrors are introduced to increase the length of the path which the reflected beam of hght must follow before arriving at the position-sensitive detector. This increases the relative movement of the light beam on the surface of the position-sensitive detector and, therefore, the overall sensitivity of the sensor.
  • the incident beam of hght is focused by a lens between the light source and the vibrating mirror Ml, so that the focal point is in the plane of the position-sensitive detector.
  • the smaller spot size and greater intensity of the incident light offers the potential for greater detector sensitivity.
  • One example is when the light beams are chopped so phase- locked loops can reduce the signal bandwidth, and increase the signal-to-noise ratio.
  • Two or more frequencies may be sampled simultaneously by directing two or more independently chopped hght beams onto a single surface Ml.
  • Electronic cross-talk may be minimized by the use of a separate position-sensitive detector for each beam. Small movements in the mirrored surface Ml result in relatively large changes in the position where the beam of light strikes the detector.
  • the position-sensitive detector is insensitive to fluctuations in the hght intensity, which lowers the overall costs (especially in arrays of such sensors).
  • Figure 1 shows a perspective schematic of the optical lever ultrasound sensor.
  • Figure 2 shows a perspective schematic of a sensor array using the optical lever ultrasound sensor.
  • Figure 3 shows a cutaway perspective of an ultrasound sensor element having a solid reflective membrane.
  • Figure 4 shows a cutaway perspective of an ultrasound sensor element having a polymer reflective membrane.
  • Figure 5 shows a cutaway perspective of an ultrasound sensor element having a cantilever with a light reflective surface.
  • Figure 6 shows a cutaway view of an ultrasound sensor element having a cantilevered light reflective surface which gives additional sensitivity by increasing the angular deflection for a given increment of acoustic pressure.
  • Figure 7 shows a multiple-bounce arrangement in which the hght beam is redirected onto the vibrating mirror surface Ml by a second, stationary mirror M2.
  • Figure 8 shows the use of two additional stationary mirrors M3 and M4 to "fold" a long lever arm into a more compact volume.
  • Figure 9 shows two independent hght beams striking a single vibrating surface, and being detected by two independent position-sensitive detectors.
  • Figure 1 shows a schematic view of an optical lever ultrasound sensor built in accordance with the present invention.
  • a hght source 11 is used to generate a narrow beam of collimated hght 15 which is directed toward a reflective surface 13 at an acute angle to the surface.
  • the hght source 11 is a laser hght source and a single mode optical fiber 12 directs the beam of hght 15 onto the reflective surface 13.
  • a source of collimated hght other than a laser may be coupled to the optical fiber 12, or a laser hght source, for instance an integrated AlGaAs/GaAs diode laser, may be used to direct a beam of hght 15 directly onto the reflective surface 13 without the use of an optical fiber 12.
  • the reflected light beam 16 from the reflective surface 13 strikes a position-sensitive hght detector (PSD) 17, which generates a signal indicative of the position at which the beam of light 16 strikes the PSD 17.
  • PSD position-sensitive hght detector
  • the reflective surface 13 is coupled to a membrane 10 which moves in reaction to an incident ultrasonic wave 14. When the membrane 10 is at rest, the reflected hght beam 16 strikes somewhere near the center of the PSD 17.
  • the small movements of the reflective surface 13 due to the incoming ultrasonic wave 14, result in large movements of the position at which the reflected light 16 strikes the PSD 17.
  • the PSD 17 is sensitive to movements of greater than 5 nm in the location of the spot of light on it. The deflection of the reflective surface 13 is thus amplified by this optical lever, the amplification being determined by the distance of the PSD 17 from the reflective sensor surface 13.
  • the output of the PSD 17 is a voltage signal which varies in proportion to the position of the light spot on the PSD surface, which in turn is proportional to the amplitude of the vibrations of the reflective sensor surface 13, and to the amplitude of the ultrasonic pressure wave 14.
  • the signal has a very low level of noise due to the measurement process or strategy.
  • the PSD 17 output is processed by the imaging electronics 18, either as a single element or as one channel of an array of sensors.
  • the leading edge of the incident pulse may be used in such an array to electronically focus on the position of the echo source. This positional information is then used to build up an image of the objects or tissue interfaces responsible for the echoes.
  • Figure 2 shows one manner of constructing an array of ultrasound sensors using the principle of the optical lever.
  • a hght source 11 preferably a laser hght source, generates a collimated beam of hght which is coupled to a bundle of optical fibers 19.
  • Each of the optical fibers 12 within the bundle 19 directs a narrow beam of hght 22 onto one of the reflective sensor elements 13 within an array of sensors 20.
  • Each beam of reflected hght 23 strikes one of the PSD elements 17 within a PSD array 21.
  • the PSD array 21 may be made from a number of separate PSD elements 17, or a large scale integrated array of detectors may be manufactured on a single chip.
  • Each set of one optical fiber 12, one reflective sensor element 13 and one PSD element 17 is analogous to the single sensor shown in Figure 1.
  • a number of sensors can be integrated together to form a linear array, a square array or other desired geometries of sensor arrays.
  • FIG. 3 shows one preferred embodiment for the reflective sensor elements for a single ultrasound sensor or an array of ultrasound sensors.
  • a substrate 24, which may be a metal, ceramic, polymer or other material, is etched or machined to form a thin membrane 26. The extent of the membrane 26 determines the aperture 25 of the sensor.
  • a reflective surface 13 is coupled to the back of the membrane 26. The reflective surface 13 may be simply the polished rear surface of the membrane 26, or the membrane 26 may be metalized to provide a reflective surface 13.
  • the material of the substrate 24 and the membrane 26 may be chosen so that it has the proper combination of density and stiffness to match the acoustic impedance of the acoustic medium to be imaged. Alternately, other well known techniques, such as quarter wave matching layers, can be used to provide good acoustic couphng.
  • the space behind the membrane 26 may be filed with a damping material to prevent excessive ringing of the sensor.
  • FIG. 4 shows another preferred embodiment of the reflective sensor element.
  • An aperture 29 is formed in a substrate 27 by etching, machining or other methods.
  • a membrane 28, which is a thin layer of metal, polymer or other material, is placed over the aperture 29.
  • a reflective surface 13 is formed on the back of the membrane 28, for instance, by polishing or metalization.
  • the material of the membrane 28 may be chosen to match the acoustic impedance of the imaging medium.
  • An advantage of this design is that the substrate material 27 may be chosen solely for its structural properties since it does not need to have the same acoustic properties as the membrane 28. Again a damping material may be added to prevent excessive ringing in the sensor.
  • Figure 5 shows a third preferred embodiment of the reflective sensor element that combines a membrane 31 with a cantilever 33.
  • An aperture 32 is formed in a substrate 30.
  • a cantilever 33 mounted on the substrate 30 contacts the membrane 31 near the middle of the aperture 32 by means of a stylus 34 or other coupling link.
  • a reflective surface 13 is formed on the back of the cantilever 33.
  • the acoustic impedance of the sensor is determined by the combined mass of the cantilever and the membrane, and the combined stiffness of the cantilever and the membrane. This allows additional flexibility in the design of the sensor for matching impedance and for tuning the sensitivity of the sensor.
  • the cantilever can also be used to linearize the pressure response of the sensor. If the response of the membrane sensor by itself does not obey Hooke's law, a cantilever with the desired force constant may be added to improve the sensor's linearity.
  • Figures 6-8 show embodiments of the present invention which use an optical amplification means to increase the amplification of the optical lever acoustic sensor. Each of the improvements which will be described can be used in combination with any of the sensor embodiments described above.
  • Figure 6 illustrates the present invention using a first approach to optical amplification of the acoustic signal.
  • This approach uses an arrangement of the cantilever which offers more sensitivity at relatively little cost.
  • this mechanical arrangement concentrates the acoustic energy impinging on the large membrane 42 into the smaller area of the post 44.
  • the top of the post 44 pushes up the cantilevered mirror 46 at a location close to its hinge 48.
  • This forms a class three lever which maximizes the angular deflection of the reflective surface for a given amplitude of movement in the membrane.
  • the increased angular deflection of the reflective surface results in greater relative movement of the reflected hght beam on the PSD which increases the overall amplification of the sensor.
  • the design is compatible with contemporary silicon/silicon dioxide micromachine technology, and permits impedance matching at particular frequency ranges of interest.
  • the acoustic impedance of the sensor is determined by the combined mass of the cantilever and the membrane, and the combined stiffness of the cantilever 50 and the membrane 42. This allows additional flexibility in the design of the sensor for matching impedance and for tuning the sensitivity of the sensor.
  • the cantilever can also be used to linearize the pressure response of the sensor. If the response of the membrane sensor by itself does not obey Hooke's law, a cantilever with the desired force constant may be added to improve the sensor's linearity.
  • Figure 7 shows an embodiment of the present invention which uses a multiple bounce approach to optical amplification of the acoustic signal.
  • the hght beam (focused onto the detector by lens LI) strikes the vibrating mirror surface Ml, and then is reflected onto a stationary mirror M2.
  • the hght beam is reflected from M2 back onto the vibrating surface Ml again.
  • Each reflection from Ml adds an increment of signal to the light beam, in the form of angular deflection, so that after two such reflection or bounces the amplitude of the angular signal is doubled.
  • With high-reflectivity mirrors many such bounces can be achieved with relatively little loss of light intensity.
  • the greater angular deflection of the incident hght beam for a given amplitude of movement of the vibrating mirror surface Ml results in greater relative movement of the reflected hght beam 16 on the PSD 17 which increases the overall amplification of the sensor.
  • the PSD 17 is only sensitive to the position of the hght beam, not the intensity, so some loss in the intensity of the hght beam due to the multiple reflections can be tolerated without affecting the overall sensitivity of the acoustic sensor.
  • the mirrors may be metal films
  • multilayer films such as of alternating Si and Si ⁇ 2 layers with quarter- wavelength matching may be used to increase the reflectivity to about 99.93%. After 1000 bounces with 99.4% reflectivity the light beam intensity is reduced to about 0.24% of the original value, while with 99.93% reflectivity it retains approximately 49.6% of the original value. Moreover, scattering and absorption are reduced by using multilayer films.
  • Figure 8 illustrates the third approach to optical amplification of the acoustic signal by increasing the "lever arm” of the optical lever.
  • the amplification of the sensor is partially determined by the length of the "lever arm", which is the distance of the PSD 17 from the reflective sensor surface 13. If sensor size were of no concern, the sensitivity of the acoustic sensor could be increased by simply making this distance larger. In practice, however, this approach would eventually make the overall size of the sensor very unwieldy.
  • this embodiment of the invention provides two stationary mirrors M3 and M4 which are used to "fold" a long lever arm into a more compact volume.
  • the signal-to- noise ratio can be improved significantly by decreasing the bandwidth of the detection circuitry.
  • the comparison of two (or more) measurements at different frequencies can be used to eliminate certain kinds of artifacts in ultrasonic images.
  • two (or more) detection frequencies are of great utility in the Doppler or color Doppler modes of medical ultrasonic imaging. Implementation of separate phase-locked loops in the sensor hardware may better achieve the optimal results, of narrow bandwidths at multiple frequencies. It is worth noting that, while Figure 9 shows how multiple hght beams can be directed at different azimuthal angles onto a vibrating mirror, it is also possible to use multiple hght beams of different wavelengths on a vibrating grating to achieve an analogous result in reciprocal space.
  • a typical piezoelectric sensor may have a sensitivity, measured in units of power per area, on the order of 10 -7 Watt cm- 2 .
  • a sensitivity measured in units of power per area, on the order of 10 -7 Watt cm- 2 .
  • signal attenuation due to absorption by biological tissue hmits the depth of view to about 200 wavelengths.
  • a 10 cm depth corresponds to a loss of about 5 orders of magnitude in signal strength.
  • an optical lever sensor can detect signals of less than 10 18 Watt cm 2 . (This corresponds to a routine situation in AFM involving a deflection of 0.01 nm against a force constant of 2 Newton ⁇ r 1 , measured in less than 10 3 second.) Thus an initial signal of 10" 2 Watt cm -2 will in theory still be detectable even after it has been attenuated by 16 orders of magnitude. With the additional improvements to the optical lever acoustic sensor described above, the practical limits of sensor sensitivity can be pushed even closer to the theoretical limit, in cost effective ways. The increased sensitivity (with respect to conventional piezoelectric transducers) can be used in several different ways.
  • the size of the sensor may be reduced, which may have advantages in terms of image resolution (both axial and lateral).
  • the dynamic range of the acquired signal may be increased, which can be used to improve image quality.
  • the power of the initial signal may be decreased, which may be a consideration for examination of certain kinds of biological tissue (e.g. eyes, embryos). Shorter wavelengths of ultrasound may be used while still viewing depths of at least 10 cm, which would improve axial resolution.
  • Range switching is accomplished relatively easily, by shortening the lever arm, or moving the PSD closer to the point of reflection.
  • a typical commercially available PSD is about 5 mm in length and can distinguish positions of incident light that are separated by more than about 5 nm. This gives a dynamic range of about 6 orders of magnitude in amplitude, or about 12 orders of magnitude in intensity. If the distance to the point of reflection is shortened by a factor of 100, the sensitivity will be less, but signals 100 times larger in amplitude (or 10,000 in intensity) may be measured.
  • the mirrors M3 and M4 in figure 4 may be adjusted to alter the lever arm.
  • the number of bounces involving mirror M2 in figure 3 may be altered by changing the incident angle of the hght beam, or the position of mirror M2 relative to the vibrating mirror
  • the phase of the signal becomes an important parameter in determining the resolution.
  • Pulsewidth or the duration of the excitation may be of less concern.
  • the small size and great sensitivity of the sensor can be used to detect the phase of the wave and identify the leading edge, rather than the entire pulse.
  • the axial resolution may be limited only by the lateral solid angle subtended by the sensor.
  • Lateral resolution also may be enhanced by the small size of the sensor. Most present designs do not detect where on a given sensor element the incident ultrasound wave impinges.
  • the lateral resolution is limited not only by the distance between sensor elements, but by the size of each element.
  • phase-locked loops independent chopping and detection can reduce the sensitivity of the system to such thermal fluctuations. Comparison of signals obtained at two or more frequencies can be used to reduce artifacts in images acquired by ultrasound. Separate phase-locked loops may be optimized in hardware, to give better results in Doppler or color Doppler ultrasound imaging. LINEAR AND SQUARE ARRAYS. This measurement strategy lends itself to high-yield, low-cost manufacture. In most implementations a separate actuator and sensor is required, instead of the single transducer. However, the low cost should compensate for the separation of functions. Moreover, the separation of functions itself should permit the use of cheaper materials that need not serve both as actuator and sensor. The sensor elements can be scaled over a wide range of sizes.
  • a ⁇ rays of such elements can be used in electronic focusing.
  • linear arrays have proved adequate in medical imaging, since two dimensions suffice for most present diagnostic purposes.
  • Square or two- dimensional arrays are also possible, giving rise to the possibility of three-dimensional ultrasonic imaging.
  • the various improvements such as the reconfigured cantilever, the multiple-bounce design, or the use of two or more incident beams on a single vibrating surface, can be incorporated into arrays.
  • the reflective surface must be in good acoustic contact with the ultrasonic medium, and should be displaced similarly by waves of similar amplitude.
  • the simplest response function is linear.
  • F kx
  • a stable force constant can be achieved in various implementations. Examples include sihcon or polymer membranes or diaphragms, sohd or fluid pistons, and micromachined springs or cantilevers.
  • Membranes or diaphragms designate thin, usually circular and planar bodies fastened at the periphery to a thicker support. Often the material itself opposes motion out of the plane of the resting surface, although another force constant may be imposed (e.g. the cantilever in Figure 2).
  • An air-fluid interface by itself provides a simple reflective surface in which surface tension opposes displacement, but also presents many design problems incompatible with a wide variety of sensor applications.
  • Membranes and diaphragms made of sohds such as silicon, or polymers of various kinds, are, however, the preferred choice in most applications.
  • Pistons designate either sohds or fluids (liquids or gases) which move along the axis of a cylindrical cavity in response to the ultrasonic wave. Problems of friction would seem to be more readily overcome with fluid pistons, such as ferromagnetic hquids.
  • the movement of the piston is typically opposed by a force proportional to the displacement, for example due to compression of a solid spring or a volume of gas.
  • SENSITIVITY Very low noise is integral to the design.
  • the optical lever in effect acts as an amplifier with a high gain and low noise. Even higher sensitivity can be achieved when the optical lever is combined with the optical amplification methods which have been described.
  • RESOLUTION High axial resolution is possible, perhaps even with longer wavelengths of ultrasound. Sensor elements smaller than the wavelength can be used, which should permit reliable measurement of phase.
  • small sensor elements can aid in improving lateral resolution, by increasing the precision with which the signal coordinates are determined.
  • the cost is low, and suitable for arrays and wide range of designs (e.g. catheter or invasive as well as non-invasive sensing).
  • a single laser source can be used for an entire a ⁇ ay of sensors, with a suitable number of optical fibers.
  • the ultrasound source or transducer/actuator can be made up of less expensive piezoelectric materials, since these do not need to play a dual role as transducer/sensors as well.
  • the sensor design involves design elements which are compatible with planar microfabrication technology, and which may be incorporated to further reduce the size of the sensors and actuators.
  • the sensor design requires only low power levels and thus is well- suited to use in portable ultrasound units.
  • the great sensitivity of the sensor requires less power in the ultrasound source as well.
  • the power needed to drive the ultrasound source or transducer/actuators can be reduced, due to the sensitivity of the transducer/sensors.
  • DYNAMIC RANGE The greater sensitivity and lower noise of the design confer an increased dynamic range. This can be used to deliver better image clarity, with its attendant clinical diagnostic values.
  • the optical lever acoustic sensor of the present invention is also suitable for use as a microphone or hydrophone in the ultrasonic or audible range. With proper calibration, the present invention would also be useful as a pressure transducer for measurement of static or dynamic fluid pressure.

Abstract

An acoustic sensor, useful as an ultrasonic transducer, microphone or hydrophone, uses an optical lever to amplify the motion of the sensor surface and convert it to an electrical signal for image processing. A beam of light (15) from a laser is directed at an oblique angle onto a reflective surface (13) coupled to a sensor membrane (31). The reflected light (16) strikes a position-sensitive light detector (PSD) (17) generating an electrical signal indicating the position of the light spot on the PSD (17). When an acoustic wave strikes the sensor membrane (31), the small movements of the reflective surface (13) result in large motions of the spot of light on the PSD (17), thereby amplifying the acoustic signal. Also disclosed is a multi-element sensor array suitable for linear array or phased array imaging. Three approaches are disclosed for increasing the sensitivity by optical amplification: 1) the vibrating mirror (46) is part of a cantilever that increases the angular deflection of the incident light beam (15); 2) a stationary mirror (M2) is positioned approximately parallel to the vibrating mirror surface; the reflected light beam is reflected back onto the vibrating mirror (M1), and picks up another increment of the acoustic signal with each reflection; 3) the effective movement of the optical lever is increased within a small volume by the use of two stationary mirrors (M3, M4) to increase the path length from the vibrating mirror (M1) to the position-sensitive detector (17). Two chopped light beams may be directed at a single vibrating surface (M1), and phase-locked loop circuitry used to reduce the signal-to-noise ratio.

Description

OPTICAL LEVER ACOUSΗC AND ULTRASOUND SENSOR
FIELD OF THE INVENTION
The present invention relates generally to diagnostic medical instrumentation and, more particularly, to ultrasonic transducers used in medical imaging. A primary objective of the present invention is to provide a robust, low-cost compact transducer with greatly increased sensitivity to ultrasound signals.
BACKGROUND OF THE INVENTION
A typical ultrasonic imaging system makes use of one or more piezoelectric transducers which act as the source (actuator) of the ultrasonic beam or signal, and which often also serve to sense the reflected signal (sensor). An electrical pulse generated by an electronic control module is converted to an ultrasonic pulse by the transducer/actuator in the probe. The probe is in contact with the body, and the ultrasonic pulse is transmitted through the probe into the body. The pulse is then absorbed by body tissues or reflected to different degrees from the boundaries between body tissues. The reflections reach the transducer/sensor at different times, which vary with the distance to the tissue boundaries. The reflections also have different energies, due to the different acoustic impedances of the tissues, as well as absorption by the intervening tissues. The transducer/sensor converts the reflections into a weak electrical signal, which contains information that can be processed into an image of the body. A great variety of ultrasonic transducers are presently in use or under development.
Shapes and sizes vary widely in order to meet special needs. Focusing by electronic or mechanical means, or some combination thereof, can be used to produce and steer a narrow ultrasonic beam of desired focal length. Likewise, mechanical and electronic focusing can be used to sense the reflections from a particular direction and distance. Phased transducer arrays of various configurations have been employed to achieve particular focusing properties, under electronic control. (The term "phased array" is taken from radar technology, in which the phase relationships of signals from multiple antennae are processed electronically to improve resolution and sensitivity.) The acquired signal is then converted into an image using analog or, depending on cost and technological considerations, digital processing. Good resolution of ultrasound images is important for medical applications. Some limits to resolution are fundamental to the physics of wave propagation (for example, acoustic shadows and reverberations, and geometric artifacts) and are best dealt with by educating the user, or by appropriate image processing algorithms. Other factors affecting resolution involve transducers and electronic instrumentation (such as axial and lateral resolution, and dynamic range) and are susceptible to improvement.
Axial resolution can be limited in part by the wavelength of the ultrasonic signal ("ultrasound" simply designates sound waves of a frequency above the audible range, with wavelengths of millimeters or less). Absorption of ultrasonic energy by body tissues tends to restrict the useful depth of field to about 200 wavelengths, due to attenuation of the signal.
Thus resolution can be improved by use of shorter wavelengths (higher frequencies) but this also implies a shallower depth of field. For a simple system with a single element and spherical or parabolic focusing, the lateral resolution is limited by the aperture of the transducer. Larger apertures provide greater resolution but shallower depth of field. The size of the transducer element or elements also can limit the resolution, since the detected signal will be known to originate from a given transducer but not any particular location on that transducer. The dynamic range of the instrument determines the useful number of gray scale levels in the image. Most commercial transducers use piezoelectric crystal elements or other materials (e.g. piezoelectric polymers such as polyvinylideneflouride) both as actuators which produce the ultrasonic pulse, and as sensors which detect the reflected signal. The physics and engineering of piezoelectric sensors are relatively well understood. The sensitivity of a simple piezoelectric sensor, such as a small block of quartz, can be greatly improved by use of a more complicated geometry, the "piezoelectric bimorph" shape. The bimorph has been used since 1930 in microphones and phonograph needle assemblies, but various design considerations such as high cost and fragility preclude its use in ultrasound transducers.
An alternative means of sensing small deflections or increments of motion is the optical lever. Optical levers have proven to be effective in routine measurements of extremely small deflections, of less than 0.01 nanometer, in atomic force microscopy (AFM). This measurement strategy can be implemented in robust ultrasound transducers at low cost, with great flexibility in design.
Accordingly, this patent application presents an acoustic sensor which uses the optical lever principle to amplify ultrasonic signals. The patent application also presents certain improvements to the optical lever acoustic sensor which use an optical amplification means to improve the amplification of the sensor. The signal amplification provided by the basic optical lever acoustic sensor is dependent on the geometry of the optical lever. Even though the optical lever arrangement presented is capable of very high signal amplification, there are practical limitations to the level of amplification possible before the size of the sensor becomes unwieldy. The improvements presented overcome these limitations by using the optical amplification means to amplify acoustic or ultrasonic signals to an even greater degree without significantly increasing the size of the sensor. SUMMARY OF THE INVENTION
The primary objective of the present invention is to provide an acoustic and ultrasound sensor which uses the optical lever principle to amplify ultrasonic signals. The optical lever acoustic sensor provides increased sensitivity to acoustic signals and an improved signal-to- noise ratio in a low cost, highly robust transducer.
It is a further objective of the present invention is to provide an optical lever acoustic and ultrasound sensor with increased sensitivity to acoustic signals. It is an important part of this objective to provide the desired increase in sensitivity by an optical amplification means which amplifies the motion of an incident acoustic wave and converts it to an electical signal for image processing. An optical amplification means is preferred because it is not subject to the same signal-to-noise limitations as the electronic amplifiers typically used in the prior art. The optical amplification means is also capable of operating in harsh environments with high levels of electromagnetic interference that would render prior art electronic amplifiers ineffective, since they amplify the electronic noise as well as the signal. It is also an objective of the invention to provide a compact acoustic sensor where the optical amplification means does not significantly increase the overall size of the sensor. At the same time, it is an objective to provide a highly sensitive acoustic sensor that is both robust and low cost to manufacture.
In distinct contrast to the piezoelectric transducer/sensors of the prior art, the present invention proposes the use of an optical lever to detect the ultrasonic reflections. The optical lever makes use of a beam of light shining at an oblique angle on a mirrored surface (e.g., a membrane or piston) in good acoustic contact with the ultrasonic medium. The reflected beam of light is directed onto a position-sensitive detector. Small movements in the mirrored surface result in relatively large changes in the position where the beam of light strikes the detector. The position-sensitive detector is insensitive to fluctuations in the hght intensity, which lowers the overall costs (especially in anrays of such sensors). The size of the sensor and of the transducer as a whole can also be reduced considerably, since all the components can be fabricated with microelectronic techniques.
In addition, the present invention proposes several improvements to the basic design of the optical lever acoustic sensor which include an optical amplification means for improving the sensitivity of the sensor. Three different approaches to the optical amplification are disclosed which can be used separately or in combination with one another.
In the first approach to optical amplification, the vibrating mirror Ml is made part of a cantilever arrangement that increases the angular deflection of the incident hght beam. The acoustic energy impinging on the large area of the diaphragm is transferred into the small area of the post The post is connected to the cantilevered mirror Ml at a point close to the hinge, in order to increase the angular deflection for a given increment of vertical deflection, and hence the overall sensitivity. In the second approach to optical amplification, a second, stationary mirror M2 is positioned approximately parallel to the vibrating mirror surface. The reflected beam of hght is directed by the stationary mirror M2 back onto the vibrating mirror Ml, and picks up a second increment of information about the acoustic signal with each increment in angular deflection. Even more reflections may be included so as to increase the total number of signal increments, the total signal in the light beam being proportional to the number of times the hght beam has been reflected from the vibrating surface Ml.
In the third approach to optical amplification, the effective moment of the optical lever is increased within a small volume by the use of additional stationary mirrors M3 and M4. The stationary mirrors are introduced to increase the length of the path which the reflected beam of hght must follow before arriving at the position-sensitive detector. This increases the relative movement of the light beam on the surface of the position-sensitive detector and, therefore, the overall sensitivity of the sensor.
Furthermore, the following improvements are made to the sensor so that it can take fuller advantage of optical amplification methods just described. The incident beam of hght is focused by a lens between the light source and the vibrating mirror Ml, so that the focal point is in the plane of the position-sensitive detector. The smaller spot size and greater intensity of the incident light offers the potential for greater detector sensitivity.
Under some conditions, it may be desirable to direct two or more beams of hght at a single vibrating surface Ml. One example is when the light beams are chopped so phase- locked loops can reduce the signal bandwidth, and increase the signal-to-noise ratio. Two or more frequencies may be sampled simultaneously by directing two or more independently chopped hght beams onto a single surface Ml. Electronic cross-talk may be minimized by the use of a separate position-sensitive detector for each beam. Small movements in the mirrored surface Ml result in relatively large changes in the position where the beam of light strikes the detector. The position-sensitive detector is insensitive to fluctuations in the hght intensity, which lowers the overall costs (especially in arrays of such sensors). The size of the sensor and of the transducer as a whole can also be reduced considerably, since all the components can be fabricated with microelectronic techniques. Other objects and advantages of the invention will no doubt occur to those skilled in the art upon reading and understanding the following detailed description along with the accompanying drawings.
BRIEF DESCRIPTION OF THE DRAWINGS Figure 1 shows a perspective schematic of the optical lever ultrasound sensor.
Figure 2 shows a perspective schematic of a sensor array using the optical lever ultrasound sensor.
Figure 3 shows a cutaway perspective of an ultrasound sensor element having a solid reflective membrane. Figure 4 shows a cutaway perspective of an ultrasound sensor element having a polymer reflective membrane.
Figure 5 shows a cutaway perspective of an ultrasound sensor element having a cantilever with a light reflective surface. Figure 6 shows a cutaway view of an ultrasound sensor element having a cantilevered light reflective surface which gives additional sensitivity by increasing the angular deflection for a given increment of acoustic pressure.
Figure 7 shows a multiple-bounce arrangement in which the hght beam is redirected onto the vibrating mirror surface Ml by a second, stationary mirror M2. Figure 8 shows the use of two additional stationary mirrors M3 and M4 to "fold" a long lever arm into a more compact volume.
Figure 9 shows two independent hght beams striking a single vibrating surface, and being detected by two independent position-sensitive detectors.
DESCRIPTION OF THE PREFERRED EMBODIMENTS
Figure 1 shows a schematic view of an optical lever ultrasound sensor built in accordance with the present invention. A hght source 11 is used to generate a narrow beam of collimated hght 15 which is directed toward a reflective surface 13 at an acute angle to the surface. In the preferred embodiment, the hght source 11 is a laser hght source and a single mode optical fiber 12 directs the beam of hght 15 onto the reflective surface 13. Alternatively, a source of collimated hght other than a laser may be coupled to the optical fiber 12, or a laser hght source, for instance an integrated AlGaAs/GaAs diode laser, may be used to direct a beam of hght 15 directly onto the reflective surface 13 without the use of an optical fiber 12.
The reflected light beam 16 from the reflective surface 13 strikes a position-sensitive hght detector (PSD) 17, which generates a signal indicative of the position at which the beam of light 16 strikes the PSD 17. The reflective surface 13 is coupled to a membrane 10 which moves in reaction to an incident ultrasonic wave 14. When the membrane 10 is at rest, the reflected hght beam 16 strikes somewhere near the center of the PSD 17. The small movements of the reflective surface 13 due to the incoming ultrasonic wave 14, result in large movements of the position at which the reflected light 16 strikes the PSD 17. The PSD 17 is sensitive to movements of greater than 5 nm in the location of the spot of light on it. The deflection of the reflective surface 13 is thus amplified by this optical lever, the amplification being determined by the distance of the PSD 17 from the reflective sensor surface 13.
The output of the PSD 17 is a voltage signal which varies in proportion to the position of the light spot on the PSD surface, which in turn is proportional to the amplitude of the vibrations of the reflective sensor surface 13, and to the amplitude of the ultrasonic pressure wave 14. The signal has a very low level of noise due to the measurement process or strategy.
The PSD 17 output is processed by the imaging electronics 18, either as a single element or as one channel of an array of sensors. The leading edge of the incident pulse may be used in such an array to electronically focus on the position of the echo source. This positional information is then used to build up an image of the objects or tissue interfaces responsible for the echoes.
Figure 2 shows one manner of constructing an array of ultrasound sensors using the principle of the optical lever. A hght source 11 , preferably a laser hght source, generates a collimated beam of hght which is coupled to a bundle of optical fibers 19. Each of the optical fibers 12 within the bundle 19 directs a narrow beam of hght 22 onto one of the reflective sensor elements 13 within an array of sensors 20. Each beam of reflected hght 23 strikes one of the PSD elements 17 within a PSD array 21. The PSD array 21 may be made from a number of separate PSD elements 17, or a large scale integrated array of detectors may be manufactured on a single chip.
Each set of one optical fiber 12, one reflective sensor element 13 and one PSD element 17 is analogous to the single sensor shown in Figure 1. Thus a number of sensors can be integrated together to form a linear array, a square array or other desired geometries of sensor arrays.
Figure 3 shows one preferred embodiment for the reflective sensor elements for a single ultrasound sensor or an array of ultrasound sensors. A substrate 24, which may be a metal, ceramic, polymer or other material, is etched or machined to form a thin membrane 26. The extent of the membrane 26 determines the aperture 25 of the sensor. A reflective surface 13 is coupled to the back of the membrane 26. The reflective surface 13 may be simply the polished rear surface of the membrane 26, or the membrane 26 may be metalized to provide a reflective surface 13.
The material of the substrate 24 and the membrane 26 may be chosen so that it has the proper combination of density and stiffness to match the acoustic impedance of the acoustic medium to be imaged. Alternately, other well known techniques, such as quarter wave matching layers, can be used to provide good acoustic couphng. The space behind the membrane 26 may be filed with a damping material to prevent excessive ringing of the sensor.
Figure 4 shows another preferred embodiment of the reflective sensor element. An aperture 29 is formed in a substrate 27 by etching, machining or other methods. A membrane 28, which is a thin layer of metal, polymer or other material, is placed over the aperture 29. A reflective surface 13 is formed on the back of the membrane 28, for instance, by polishing or metalization. The material of the membrane 28 may be chosen to match the acoustic impedance of the imaging medium. An advantage of this design is that the substrate material 27 may be chosen solely for its structural properties since it does not need to have the same acoustic properties as the membrane 28. Again a damping material may be added to prevent excessive ringing in the sensor.
Figure 5 shows a third preferred embodiment of the reflective sensor element that combines a membrane 31 with a cantilever 33. An aperture 32 is formed in a substrate 30. A cantilever 33 mounted on the substrate 30 contacts the membrane 31 near the middle of the aperture 32 by means of a stylus 34 or other coupling link. A reflective surface 13 is formed on the back of the cantilever 33.
In this design, the acoustic impedance of the sensor is determined by the combined mass of the cantilever and the membrane, and the combined stiffness of the cantilever and the membrane. This allows additional flexibility in the design of the sensor for matching impedance and for tuning the sensitivity of the sensor. The cantilever can also be used to linearize the pressure response of the sensor. If the response of the membrane sensor by itself does not obey Hooke's law, a cantilever with the desired force constant may be added to improve the sensor's linearity. Figures 6-8 show embodiments of the present invention which use an optical amplification means to increase the amplification of the optical lever acoustic sensor. Each of the improvements which will be described can be used in combination with any of the sensor embodiments described above.
Figure 6 illustrates the present invention using a first approach to optical amplification of the acoustic signal. This approach uses an arrangement of the cantilever which offers more sensitivity at relatively little cost. In analogy to the leverage provided by the malleus and stapes of the human ear, this mechanical arrangement concentrates the acoustic energy impinging on the large membrane 42 into the smaller area of the post 44. The top of the post 44 pushes up the cantilevered mirror 46 at a location close to its hinge 48. This forms a class three lever which maximizes the angular deflection of the reflective surface for a given amplitude of movement in the membrane. The increased angular deflection of the reflective surface results in greater relative movement of the reflected hght beam on the PSD which increases the overall amplification of the sensor. The design is compatible with contemporary silicon/silicon dioxide micromachine technology, and permits impedance matching at particular frequency ranges of interest.
In this design, the acoustic impedance of the sensor is determined by the combined mass of the cantilever and the membrane, and the combined stiffness of the cantilever 50 and the membrane 42. This allows additional flexibility in the design of the sensor for matching impedance and for tuning the sensitivity of the sensor. The cantilever can also be used to linearize the pressure response of the sensor. If the response of the membrane sensor by itself does not obey Hooke's law, a cantilever with the desired force constant may be added to improve the sensor's linearity.
Figure 7 shows an embodiment of the present invention which uses a multiple bounce approach to optical amplification of the acoustic signal. The hght beam (focused onto the detector by lens LI) strikes the vibrating mirror surface Ml, and then is reflected onto a stationary mirror M2. The hght beam is reflected from M2 back onto the vibrating surface Ml again. Each reflection from Ml adds an increment of signal to the light beam, in the form of angular deflection, so that after two such reflection or bounces the amplitude of the angular signal is doubled. With high-reflectivity mirrors, many such bounces can be achieved with relatively little loss of light intensity. The greater angular deflection of the incident hght beam for a given amplitude of movement of the vibrating mirror surface Ml results in greater relative movement of the reflected hght beam 16 on the PSD 17 which increases the overall amplification of the sensor. The PSD 17 is only sensitive to the position of the hght beam, not the intensity, so some loss in the intensity of the hght beam due to the multiple reflections can be tolerated without affecting the overall sensitivity of the acoustic sensor. The mirrors may be metal films
(such as Cr, Cu, Ag, or Au) which can achieve reflectivities of about 99.4%. After 100 bounces with 99.4% reflectivity the hght beam intensity would be 54.78% of the original value, which is quite acceptable. If greater numbers of bounces are required to achieve the desired amplification, multilayer films (such as of alternating Si and Siθ2 layers with quarter- wavelength matching) may be used to increase the reflectivity to about 99.93%. After 1000 bounces with 99.4% reflectivity the light beam intensity is reduced to about 0.24% of the original value, while with 99.93% reflectivity it retains approximately 49.6% of the original value. Moreover, scattering and absorption are reduced by using multilayer films.
Figure 8 illustrates the third approach to optical amplification of the acoustic signal by increasing the "lever arm" of the optical lever. As mentioned previously, the amplification of the sensor is partially determined by the length of the "lever arm", which is the distance of the PSD 17 from the reflective sensor surface 13. If sensor size were of no concern, the sensitivity of the acoustic sensor could be increased by simply making this distance larger. In practice, however, this approach would eventually make the overall size of the sensor very unwieldy. In order to overcome the problem of size, this embodiment of the invention provides two stationary mirrors M3 and M4 which are used to "fold" a long lever arm into a more compact volume. Doubling the path length the reflected hght beam travels between the reflective sensor surface 13 and the PSD 17 doubles the relative movement of the hght beam on the PSD, thereby doubhng the amplification provided by the optical lever. As in the previous embodiment, with highly reflective mirrors the amplification of the sensor can be increased tremendously by multiple reflections of the hght beam to increase the length of the lever arm. Figure 9 shows two independent light beams 64, 66 striking a single vibrating surface 68, and being detected by two independent position-sensitive detectors 60, 62. This illustrates the use of multiple independent phase-locked loops, each chopping a hght beam at a unique frequency, to measure a given frequency component of the acoustic excitation. The signal-to- noise ratio can be improved significantly by decreasing the bandwidth of the detection circuitry. The comparison of two (or more) measurements at different frequencies can be used to eliminate certain kinds of artifacts in ultrasonic images. Finally, two (or more) detection frequencies are of great utility in the Doppler or color Doppler modes of medical ultrasonic imaging. Implementation of separate phase-locked loops in the sensor hardware may better achieve the optimal results, of narrow bandwidths at multiple frequencies. It is worth noting that, while Figure 9 shows how multiple hght beams can be directed at different azimuthal angles onto a vibrating mirror, it is also possible to use multiple hght beams of different wavelengths on a vibrating grating to achieve an analogous result in reciprocal space.
TECHNICAL DISCUSSION SENSΓΠVΠΎ.
A typical piezoelectric sensor may have a sensitivity, measured in units of power per area, on the order of 10-7 Watt cm-2. When operating at a recommended biological threshold hmit of about 102 Watt cm 2, signal attenuation due to absorption by biological tissue hmits the depth of view to about 200 wavelengths. For a 3 MHz signal, a 10 cm depth corresponds to a loss of about 5 orders of magnitude in signal strength.
In contrast, an optical lever sensor can detect signals of less than 10 18 Watt cm 2. (This corresponds to a routine situation in AFM involving a deflection of 0.01 nm against a force constant of 2 Newton πr1, measured in less than 103 second.) Thus an initial signal of 10"2 Watt cm-2 will in theory still be detectable even after it has been attenuated by 16 orders of magnitude. With the additional improvements to the optical lever acoustic sensor described above, the practical limits of sensor sensitivity can be pushed even closer to the theoretical limit, in cost effective ways. The increased sensitivity (with respect to conventional piezoelectric transducers) can be used in several different ways. The size of the sensor may be reduced, which may have advantages in terms of image resolution (both axial and lateral). The dynamic range of the acquired signal may be increased, which can be used to improve image quality. The power of the initial signal may be decreased, which may be a consideration for examination of certain kinds of biological tissue (e.g. eyes, embryos). Shorter wavelengths of ultrasound may be used while still viewing depths of at least 10 cm, which would improve axial resolution.
DYNAMIC RANGE.
In practice, it is convenient to limit the dynamic range to 12 orders of magnitude or less. The practical constraints on dynamic range are the amplitude of the deflection produced by the ultrasound excitation of the membrane, diaphragm, or piston; and the size of the position-sensitive detector (PSD). A nearly linear response of the vibrating surface to the excitation is desirable, and this will constrain the acceptable amplitude.
Should larger amplitudes be acceptable for the vibrating surface in a given implementation, it may be useful to adjust the sensitivity. Range switching is accomplished relatively easily, by shortening the lever arm, or moving the PSD closer to the point of reflection. A typical commercially available PSD is about 5 mm in length and can distinguish positions of incident light that are separated by more than about 5 nm. This gives a dynamic range of about 6 orders of magnitude in amplitude, or about 12 orders of magnitude in intensity. If the distance to the point of reflection is shortened by a factor of 100, the sensitivity will be less, but signals 100 times larger in amplitude (or 10,000 in intensity) may be measured.
The improvements may permit better or more convenient utilization of the dynamic range. For example, the mirrors M3 and M4 in figure 4 may be adjusted to alter the lever arm. The number of bounces involving mirror M2 in figure 3 may be altered by changing the incident angle of the hght beam, or the position of mirror M2 relative to the vibrating mirror
Ml.
RESOLUTION.
When a sensor is smaller in size than the wavelength of the detected signal, the phase of the signal becomes an important parameter in determining the resolution. Pulsewidth or the duration of the excitation may be of less concern. For example, the small size and great sensitivity of the sensor can be used to detect the phase of the wave and identify the leading edge, rather than the entire pulse. If the arriving edge detection is very efficient, the axial resolution may be limited only by the lateral solid angle subtended by the sensor. Lateral resolution also may be enhanced by the small size of the sensor. Most present designs do not detect where on a given sensor element the incident ultrasound wave impinges.
Therefore, the lateral resolution is limited not only by the distance between sensor elements, but by the size of each element.
THERMAL AND OTHER NOISE. Thermal and other energy fluctuations will provide a background of vibrations in the ultrasound frequency range, for which the probability can be readily estimated. Well known techniques exist for addressing this problem, such as moving the signal to a part of the frequency domain which is lower in noise, or the use of a lock-in amplifier.
The use of multiple beams, phase-locked loops, independent chopping and detection can reduce the sensitivity of the system to such thermal fluctuations. Comparison of signals obtained at two or more frequencies can be used to reduce artifacts in images acquired by ultrasound. Separate phase-locked loops may be optimized in hardware, to give better results in Doppler or color Doppler ultrasound imaging. LINEAR AND SQUARE ARRAYS. This measurement strategy lends itself to high-yield, low-cost manufacture. In most implementations a separate actuator and sensor is required, instead of the single transducer. However, the low cost should compensate for the separation of functions. Moreover, the separation of functions itself should permit the use of cheaper materials that need not serve both as actuator and sensor. The sensor elements can be scaled over a wide range of sizes. Aπrays of such elements can be used in electronic focusing. Generally linear arrays have proved adequate in medical imaging, since two dimensions suffice for most present diagnostic purposes. Square or two- dimensional arrays are also possible, giving rise to the possibility of three-dimensional ultrasonic imaging. It should be noted that the various improvements such as the reconfigured cantilever, the multiple-bounce design, or the use of two or more incident beams on a single vibrating surface, can be incorporated into arrays.
THE REFLECTIVE SURFACE. The reflective surface must be in good acoustic contact with the ultrasonic medium, and should be displaced similarly by waves of similar amplitude. The simplest response function is linear. For example, the surface response will obey Hooke's law (F = kx) if the force opposing displacement is proportional to the magnitude of the displacement The displacement due to the incident ultrasonic wave or pulse must also be quickly damped, in order to avoid subsequent ringing or spurious signal.
A stable force constant can be achieved in various implementations. Examples include sihcon or polymer membranes or diaphragms, sohd or fluid pistons, and micromachined springs or cantilevers.
Membranes or diaphragms designate thin, usually circular and planar bodies fastened at the periphery to a thicker support. Often the material itself opposes motion out of the plane of the resting surface, although another force constant may be imposed (e.g. the cantilever in Figure 2). An air-fluid interface by itself provides a simple reflective surface in which surface tension opposes displacement, but also presents many design problems incompatible with a wide variety of sensor applications. Membranes and diaphragms made of sohds such as silicon, or polymers of various kinds, are, however, the preferred choice in most applications.
Pistons designate either sohds or fluids (liquids or gases) which move along the axis of a cylindrical cavity in response to the ultrasonic wave. Problems of friction would seem to be more readily overcome with fluid pistons, such as ferromagnetic hquids. The movement of the piston is typically opposed by a force proportional to the displacement, for example due to compression of a solid spring or a volume of gas.
The above examples serve simply to illustrate ways to design or fabricate a reflective surface with a reproducible and sensitive response to ultrasonic excitation.
CONCLUSION, RAMIFICATIONS, AND SCOPE The present invention can be incorporated in various alternatives to the embodiments described above.
Both analog and digital signal processing can be used with virtually no changes from current imaging technology. This allows full use of the great art and ingenuity presently achieved in ultrasound signal processing, to deliver the maximum diagnostic value in medical care.
SENSITIVITY. Very low noise is integral to the design. The optical lever in effect acts as an amplifier with a high gain and low noise. Even higher sensitivity can be achieved when the optical lever is combined with the optical amplification methods which have been described. RESOLUTION. High axial resolution is possible, perhaps even with longer wavelengths of ultrasound. Sensor elements smaller than the wavelength can be used, which should permit reliable measurement of phase.
Similarly small sensor elements can aid in improving lateral resolution, by increasing the precision with which the signal coordinates are determined.
ROBUST. Optical levers have already proven to be a robust measurement strategy.
LOW COST. The cost is low, and suitable for arrays and wide range of designs (e.g. catheter or invasive as well as non-invasive sensing). A single laser source can be used for an entire aιτay of sensors, with a suitable number of optical fibers. The ultrasound source or transducer/actuator can be made up of less expensive piezoelectric materials, since these do not need to play a dual role as transducer/sensors as well.
SUITED TO MINIATURIZAΗON AND MASS-PRODUCTION. The sensor design involves design elements which are compatible with planar microfabrication technology, and which may be incorporated to further reduce the size of the sensors and actuators.
LOW-POWER. The sensor design requires only low power levels and thus is well- suited to use in portable ultrasound units. The great sensitivity of the sensor requires less power in the ultrasound source as well. The power needed to drive the ultrasound source or transducer/actuators can be reduced, due to the sensitivity of the transducer/sensors. DYNAMIC RANGE. The greater sensitivity and lower noise of the design confer an increased dynamic range. This can be used to deliver better image clarity, with its attendant clinical diagnostic values.
OTHER APPLICATIONS. Though specifically conceived for use as an ultrasound transducer, the optical lever acoustic sensor of the present invention is also suitable for use as a microphone or hydrophone in the ultrasonic or audible range. With proper calibration, the present invention would also be useful as a pressure transducer for measurement of static or dynamic fluid pressure.
While the foregoing description contains many specific details, these should not be construed as limitations on the scope of the invention, but rather as an exemplification of some of its preferred embodiments. Many other variations are possible and will no doubt occur to others upon reading and understanding the preceding description. Accordingly, the scope of the invention should be determined, not by the embodiment illustrated, but by the appended claims and their legal equivalents.

Claims

I claim:
1. An acoustic sensor comprising: a reflective surface responsive to incident sound waves, a hght beam incident upon said reflective surface, a reflected hght beam which is the reflection of said incident hght beam from said reflective surface, a position sensitive light detector so arranged as to sense the position of said reflected light beam, said position sensitive light detector being sensitive to the position of said reflected hght beam on said hght detector and said position sensitive hght detector being insensitive to changes in the intensity of said reflected hght beam.
2. The acoustic sensor of claim 1 wherein said incident hght beam is incident upon said reflective surface at an acute angle, and wherein the position of said reflected hght beam is indicative of the position of said reflective surface.
3. The acoustic sensor of claim 2 wherein the motion of said reflected light beam at said position sensitive hght detector is greater than the motion of said reflective surface, thereby serving to amplify the motion of said reflective surface.
4. The acoustic sensor of claim 1 wherein said reflective surface comprises a membrane responsive to incident sound waves.
5. The acoustic sensor of claim 4 wherein said membrane is formed of a polymer material.
6. The acoustic sensor of claim 1 wherein said reflective surface comprises a cantilever which is responsive to incident sound waves.
7. The acoustic sensor of claim 6 wherein said cantilever is responsive to the motion of a membrane which is responsive to incident sound waves.
8. The acoustic sensor of claim 1 further comprising a light source for producing said incident hght beam.
9. The acoustic sensor of claim 8 further comprising an optical fiber for directing said incident hght beam from said light source onto said reflective surface.
10. The acoustic sensor of claim 8 wherein said light source comprises a laser hght source.
11. The acoustic sensor of claim 10 further comprising an optical fiber for directing said incident light beam from said laser hght source onto said reflective surface.
12. An acoustic sensor array comprising: a plurality of reflective surfaces, each independently responsive to incident sound waves, at least one hght beam incident upon said reflective surfaces, a plurality of reflected hght beams which are the reflection of said at least one incident light beam from said reflective surfaces, a plurality of position sensitive hght detectors so arranged as to sense the positions of said reflected hght beams, said position sensitive hght detectors being sensitive to the position of said reflected hght beams on said hght detectors and said position sensitive hght detectors being insensitive to changes in the intensity of said reflected hght beams.
13. The acoustic sensor of claim 12 comprising a plurality of incident light beams, each of said incident light beams being incident upon one of said plurality of reflective surfaces.
14. A method of detecting sound waves comprising the steps of: directing an incoming beam of hght onto a reflective surface responsive to incident sound waves, detecting the position of a reflected hght beam, which is the reflection of said incoming beam of hght from said reflective surface, converting the detected position of said reflected hght beam into a signal indicative of the movement of said reflective surface in response to said incident sound waves.
15. The acoustic sensor array of claim 12, wherein said at least one light beam comprises a single light beam which is incident on all of said plurality of reflective surfaces and said plurality of reflected light beams are the reflections of said single hght beam off of said plurality of reflective surfaces.
16. The acoustic sensor array of claim 12, wherein said at least one light beam comprises a plurality of hght beams and each of said plurality of hght beams is reflected off of one of said plurality of reflective surfaces to form said plurality of reflected light beams.
17. An acoustic sensor comprising: a first reflective surface responsive to incident sound waves, a hght beam incident upon said reflective surface, a reflected light beam which is the reflection of said incident hght beam from said first reflective surface, a position sensitive light detector so arranged as to sense the position of said reflected light beam, and optical means for amplifying a movement of said position of said reflected light beam on said position sensitive hght detector in response to said incident sound waves.
18. The acoustic sensor of claim 17 wherein said optical means for amplifying comprises at least one stationary reflective surface, said reflected hght beam being reflected at least once from said at least one stationary reflective surface before striking said position sensitive hght detector.
19. The acoustic sensor of claim 18 wherein said at least one stationary reflective surface amplifies the movement of said position of said reflected light beam on said position sensitive hght detector by increasing the path length traveled by said reflected hght beam from said first reflective surface to said position sensitive hght detector.
20. The acoustic sensor of claim 19 wherein said at least one stationary reflective surface comprises at least two stationary reflective surfaces, said reflected hght beam being reflected at least once from each of said at least two stationary reflective surfaces before striking said position sensitive light detector.
21. The acoustic sensor of claim 20 wherein said reflected hght beam is reflected multiple times from each of said at least two stationary reflective surfaces before striking said position sensitive hght detector.
22. The acoustic sensor of claim 18 wherein said reflected light beam is reflected by said at least one stationary reflective surface back onto said first reflective surface at least once before striking said position sensitive hght detector.
23. The acoustic sensor of claim 22 wherein said reflected hght beam is reflected multiple times from said at least one stationary reflective surface back onto said first reflective surface before striking said position sensitive light detector.
24. An acoustic sensor comprising: a reflective surface responsive to incident sound waves, a first hght beam incident upon said reflective surface, a second reflected hght beam which is the reflection of said first incident hght beam from said reflective surface, a second hght beam incident upon said reflective surface, a second reflected hght beam which is the reflection of said second incident hght beam from said reflective surface, a first position sensitive hght detector so arranged as to sense the position of said first reflected hght beam, and a second position sensitive light detector so arranged as to sense the position of said second reflected light beam.
25. The acoustic sensor of claim 24 wherein said first light beam has a first wavelength and said second light beam has a second wavelength which is different from said first wavelength.
26. The acoustic sensor of claim 24 further comprising a first phase-locked loop circuit means, said first hght beam being chopped at a first frequency for detection by said first phase-locked loop circuit means.
27. The acoustic sensor of claim 26 further comprising a second phase-locked loop circuit means, said second hght beam being chopped at a second frequency for detection by said second phase-locked loop circuit means.
PCT/US1993/005442 1992-06-08 1993-06-08 Optical lever acoustic and ultrasound sensor WO1993025874A1 (en)

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US07/895,544 US5249163A (en) 1992-06-08 1992-06-08 Optical lever for acoustic and ultrasound sensor
US08/042,726 US5339289A (en) 1992-06-08 1993-04-05 Acoustic and ultrasound sensor with optical amplification
US08/042,726 1993-04-05

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Cited By (6)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
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US11116478B2 (en) 2016-02-17 2021-09-14 Sanolla Ltd. Diagnosis of pathologies using infrasonic signatures

Families Citing this family (36)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US5728089A (en) * 1993-06-04 1998-03-17 The Regents Of The University Of California Microfabricated structure to be used in surgery
US5633552A (en) * 1993-06-04 1997-05-27 The Regents Of The University Of California Cantilever pressure transducer
AU6953994A (en) * 1993-06-04 1995-01-03 Regents Of The University Of California, The Microfabricated acoustic source and receiver
FR2745377B1 (en) * 1996-02-22 1998-03-20 Gec Alsthom T D Balteau OPTICAL VIBRATION SENSOR
DE19822286B4 (en) * 1998-03-23 2012-08-09 Harald Fuchs Acoustic Microscope
US6657733B1 (en) 1998-06-30 2003-12-02 Lockheed Martin Corporation Method and apparatus for detecting ultrasonic surface displacements using post-collection optical amplification
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US7815590B2 (en) 1999-08-05 2010-10-19 Broncus Technologies, Inc. Devices for maintaining patency of surgically created channels in tissue
US7422563B2 (en) 1999-08-05 2008-09-09 Broncus Technologies, Inc. Multifunctional tip catheter for applying energy to tissue and detecting the presence of blood flow
US6749606B2 (en) 1999-08-05 2004-06-15 Thomas Keast Devices for creating collateral channels
US6712812B2 (en) 1999-08-05 2004-03-30 Broncus Technologies, Inc. Devices for creating collateral channels
US7022088B2 (en) * 1999-08-05 2006-04-04 Broncus Technologies, Inc. Devices for applying energy to tissue
US7175644B2 (en) * 2001-02-14 2007-02-13 Broncus Technologies, Inc. Devices and methods for maintaining collateral channels in tissue
EP1143864B1 (en) 1999-08-05 2004-02-04 Broncus Technologies, Inc. Methods and devices for creating collateral channels in the lungs
AU2001253654A1 (en) * 2000-04-27 2001-11-12 Medtronic, Inc. Vibration sensitive ablation apparatus and method
US6567572B2 (en) * 2000-06-28 2003-05-20 The Board Of Trustees Of The Leland Stanford Junior University Optical displacement sensor
CA2324572A1 (en) * 2000-10-26 2002-04-26 Gerry M. Kane Digital vibration transducer
US7708712B2 (en) 2001-09-04 2010-05-04 Broncus Technologies, Inc. Methods and devices for maintaining patency of surgically created channels in a body organ
US8002740B2 (en) 2003-07-18 2011-08-23 Broncus Technologies, Inc. Devices for maintaining patency of surgically created channels in tissue
US8308682B2 (en) 2003-07-18 2012-11-13 Broncus Medical Inc. Devices for maintaining patency of surgically created channels in tissue
US20050285025A1 (en) * 2004-06-29 2005-12-29 Mikhail Boukhny Optical noninvasive pressure sensor
US8409167B2 (en) 2004-07-19 2013-04-02 Broncus Medical Inc Devices for delivering substances through an extra-anatomic opening created in an airway
US20070291440A1 (en) * 2006-06-15 2007-12-20 Dueber Thomas E Organic encapsulant compositions based on heterocyclic polymers for protection of electronic components
WO2008157445A1 (en) * 2007-06-15 2008-12-24 Luidia Inc. Interactivity in a large flat panel display
JP2011169748A (en) * 2010-02-18 2011-09-01 Olympus Corp Optical-lever cantilever displacement detecting mechanism
DE102010033951B4 (en) 2010-08-10 2019-05-29 Universität Paderborn Arrangement and method for multi-dimensional measurement of vibrations of an object
WO2012030595A2 (en) 2010-08-30 2012-03-08 Alcon Research, Ltd. Optical sensing system including electronically switched optical magnification
US9345532B2 (en) 2011-05-13 2016-05-24 Broncus Medical Inc. Methods and devices for ablation of tissue
US8709034B2 (en) 2011-05-13 2014-04-29 Broncus Medical Inc. Methods and devices for diagnosing, monitoring, or treating medical conditions through an opening through an airway wall
WO2013078235A1 (en) 2011-11-23 2013-05-30 Broncus Medical Inc Methods and devices for diagnosing, monitoring, or treating medical conditions through an opening through an airway wall
KR20150118494A (en) * 2014-04-14 2015-10-22 삼성전자주식회사 ultrasonic imaging apparatus and method for controlling a ultrasonic imaging apparatus
CN105628178A (en) * 2016-03-08 2016-06-01 马翼 Alarming device for vibration detection based on Internet of Things
WO2017152363A1 (en) * 2016-03-08 2017-09-14 马翼 Internet of things-based alarm device for use in vibration detection
EP3606457A4 (en) 2017-04-03 2021-04-21 Broncus Medical Inc. Electrosurgical access sheath
CN110595601B (en) * 2019-04-26 2021-10-15 深圳市豪视智能科技有限公司 Bridge vibration detection method and related device
CN110539074B (en) * 2019-10-18 2021-01-22 天津工业大学 High-efficient multi freedom ultrasonic vibration assists two-sided laser beam machining device

Citations (2)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US3708231A (en) * 1969-11-10 1973-01-02 G Walters Precision angle measuring device
DE3607868A1 (en) * 1986-03-10 1987-09-17 Schult Roger Device for scanning mechanical vibrations by means of optoelectronic elements using the reflection principle

Family Cites Families (3)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US4446543A (en) * 1979-07-02 1984-05-01 The United States Of America As Represented By The Secretary Of The Navy Optical resonator single-mode fiber hydrophone
US4998225A (en) * 1979-12-10 1991-03-05 The United States Of America As Represented By The Secretary Of The Navy Dual beam doppler shift hydrophone
US4422167A (en) * 1981-06-25 1983-12-20 The United States Of America As Represented By The Secretary Of The Navy Wide-area acousto-optic hydrophone

Patent Citations (2)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US3708231A (en) * 1969-11-10 1973-01-02 G Walters Precision angle measuring device
DE3607868A1 (en) * 1986-03-10 1987-09-17 Schult Roger Device for scanning mechanical vibrations by means of optoelectronic elements using the reflection principle

Non-Patent Citations (2)

* Cited by examiner, † Cited by third party
Title
REVIEW OF SCIENTIFIC INSTRUMENTS vol. 58, no. 8, September 1987, NEW YORK US pages 1678 - 1681 FRANCINI ET AL 'opto electronic system for displacement and vibration measurements' *
ROYER D., DIELESAINT E.: "MESURES OPTIQUES DE DEPLACEMENTS D'AMPLITUDE 10-4 A 102 ANGSTROM APPLICATION AUX ONDES ELASTIQUES.", REVUE DE PHYSIQUE APPLIQUEE, E D P SCIENCES, FR, vol. 24., no. 08., 1 August 1989 (1989-08-01), FR, pages 833 - 846., XP000068102, ISSN: 0035-1687, DOI: 10.1051/rphysap:01989002408083300 *

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US5533976A (en) * 1994-07-15 1996-07-09 Allergan, Inc. Reusable cartridge assembly for a phaco machine
US5697910A (en) * 1994-07-15 1997-12-16 Allergan Reusable cartridge assembly for a phaco machine
CN103048103A (en) * 2012-04-23 2013-04-17 北京航空航天大学 Non-contact modal test system and method
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