Abstract: An acousto-optic imaging system includes: an ultrasonic wave source for irradiating an imaged object with an ultrasonic wave; an acoustic lens for converting a scattered wave of the ultrasonic wave to a plane wave; a light-transmitting acoustic medium provided in an area on an opposite side of the imaged object with respect to the acoustic lens; a light source for outputting a monochromatic light plane wave; an image-forming lens arranged so as to condense diffraction light of the monochromatic light plane wave which is produced in the light-transmitting acoustic medium; an image-receiving section for obtaining an optical image formed by the image-forming lens; and a distortion compensation section for correcting a distortion of the optical image or a distortion.

Abstract: A method for determining effects of perforation on a rock formation includes obtaining a sample of the rock formation. A perforation tunnel is created in the sample of the rock formation. The core sample is either subdivided into subsamples and a three dimensional tomographic image is made of each subsample and/or a three dimensional tomographic image is made of the sample of rock formation and the image thereof is segmented into sub images of selected subvolumes of the rock formation sample. At least one physical property of the rock formation is estimated from each tomographic image.

Abstract: A quantitative evaluation method, a method for manufacturing a silicon wafer, and a silicon wafer manufactured by the method, enabling more efficient evaluation of the concentration of atomic vacancies existing in a silicon wafer. The quantitative evaluation method includes steps of: oscillating, in a state in which an external magnetic field is applied to a silicon wafer (26) while keeping the silicon wafer (26) at a constant temperature, an ultrasonic wave pulse and receiving a measurement wave pulse obtained after the ultrasonic wave pulse is propagated through the silicon wafer (26) for detecting a phase difference between the ultrasonic wave pulse and the measurement wave pulse; and calculating an elastic constant from the phase difference. The external magnetic field is changed to calculate the elastic constant corresponding to a change in the external magnetic field for evaluating a concentration of atomic vacancies in the silicon wafer (26).

Abstract: An ultrasonic diagnostic apparatus that performs high acoustic pressure and low acoustic pressure ultrasonic transmissions by switching at predetermined timing in the enhanced ultrasonography, and displays concurrently a replenishment image obtained through the low acoustic pressure transmission in real time like a moving picture, and a pre-flash image obtained through the low acoustic pressure transmission immediately before switching to the high acoustic pressure transmission like a still image to allow the operator to understand the structure at the level of capillaries. It is also possible to display a selected image obtained through the low acoustic pressure transmission at an arbitrary timing instead of the pre-flash image.

Abstract: A Confocal Interferometry microscope for use with a suitably selected acoustic emitter and acoustic detector for providing three-dimensional information on the state of an object is presented. The microscope has a coherent wavelength source for producing a coherent beam, scanning means for moving said coherent beam in a suitably selected pattern, and means for producing and focusing an object beam and an interference beam to an object focal point and an interference focal point, respectively. The object beam has a transmission path of essentially the same length of the transmission path of the interference beam. The object beam intercepts an object at the object focal point while the interference beam passes by the object. There are also means for defining the object beam and the interference beam based on the position of the object focal point and the geometry of the convergence angles and means for producing an interference pattern between the object focal point and the interference focal point.

Abstract: An ultrasonic transducer driving circuit configured to supply an output current and/or an output voltage to an output line for driving an ultrasonic transducer is provided. The ultrasonic transducer driving circuit includes a first current discharge circuit configured to allow a current arising from electric charges accumulated in the ultrasonic transducer to flow from the output line to ground when the output line is at a positive voltage, and a second current discharge circuit configured to allow the current arising from the electric charges accumulated in the ultrasonic transducer to flow from ground to the output line when the output line is at a negative voltage. The first current discharge circuit and the second current discharge circuit are controlled based on the output current and/or the output voltage.

Abstract: A system for inspecting a wind turbine blade having a pair of shells surrounding a shear web. The system includes a scanning machine for taking images of an interior portion of the shells of the wind turbine blade, a measuring apparatus for taking numerous measurements of a defect imaged within the shells of the wind turbine blade, and a look-up table for ascertaining the theoretical strength of the wind turbine blade.

Abstract: A photoacoustic imaging apparatus for detecting a photoacoustic image of a detected object is provided. The photoacoustic imaging apparatus includes a laser probe and a transparent ultrasonic sensor. The laser probe is configured to emit a laser beam. The transparent ultrasonic sensor is disposed over the laser probe. The laser beam emitted from the laser probe passes through the transparent ultrasonic sensor to be transmitted to the detected object.

Abstract: Disclosed is an ultrasonic probe wherein the warpage of a CMUT due to thermal stress produced at the joint between a backing layer and the CMUT is minimized, thereby improving the durability of the bond between the CMUT and the backing layer. To accomplish this the ultrasonic probe is provided with: a CMUT (20) having vibratory elements that change the electromechanical coupling coefficient or sensitivity according to the bias voltage to be applied; a backing layer (22) adhered to the rear side of the ultrasonic transmission surface of the CMUT (20); and a thermal-stress balancing member (24) to be adhered to the backing layer (22) while being disposed facing the CMUT (20) in such a manner that the backing layer (22) is sandwiched therebetween so as to minimize the warpage of the CMUT (20) due to thermal stress produced between the CMUT (20).

Abstract: An imaging method using shear waves for observing a viscoelastic medium, comprising: several successive excitation steps j during which elastic shear waves are generated respectively at different excitation loci (Lj) in the viscoelastic medium by an imaging device, the different excitation loci being separated from one another by a maximum distance Dm, an imaging step corresponding to each excitation step j, in which a set j of successive raw images Imj(tk) of the viscoelastic medium at times tk are determined during propagation of the shear wave, the raw images having a resolution R which is larger than the maximum distance Dm, an averaging step in which raw images Imj(tk) corresponding to the same relative time tk are averaged to determine an average image Im?(tk).

Abstract: An ultrasound transducer includes a substrate and a lower electrode layer, a lower insulating layer, an upper insulating layer, and an upper electrode layer. The lower insulating layer and the upper insulating layer are arranged to be opposed to each other via an air gap section. The upper insulating layer and the lower insulating layer are different in a material and thickness and satisfy Equation 1 below. In Equation 1, K1 represents a relative dielectric constant of the lower insulating layer, K2 represents a relative dielectric constant of the upper insulating layer, T1 represents thickness of the lower insulating layer, T2 represents thickness of the upper insulating layer, ?1(x) represents a charge density distribution in the lower insulating layer, and ?2(y) represents a charge density distribution in the upper insulating layer.

Abstract: A non-contact near field high resolution acoustic imaging system of a sample, the system including an acoustic wave generator generating a plurality of acoustic waves a ultrasonic horn amplifying the waves to an amplitude of between about 20 microns and about 300 microns, and a frequency between about 20 kHz and about 40 khz. The ultrasonic horn further directs the amplified waves to impinge upon the sample. On contact between the waves and the sample, a plurality of transmitted energy is transmitted to the sample, a plurality of longitudinal displacements and surface acoustic wave displacements in the sample are created. An adjustable separation distance lies between the sample and the ultrasonic horn, the distance adjusted to maximize the transmitted energy. The distance is preferably greater than the maximum displacement of the ultrasonic horn, or approximately 0.1 mm.

Abstract: A method, and corresponding apparatus, of imaging sub-surface features at a plurality of locations on a sample includes coupling an ultrasonic wave into a sample at a first lateral position. The method then measures the amplitude and phase of ultrasonic energy near the sample with a tip of an atomic force microscope. Next, the method couples an ultrasonic wave into a sample at a second lateral position and the measuring step is repeated for the second lateral position. Overall, the present system and methods achieve high resolution sub-surface mapping of a wide range of samples, including silicon wafers. It is notable that when imaging wafers, backside contamination is minimized.

Abstract: A plane or volume is scanned with ultrasound. Electronic movement of apertures is used during the scanning. Scanning with the apertures is interleaved. The apertures move along the array in opposite directions, preventing or limiting large temporal discontinuity. For example, two apertures begin at similar angles on a two-dimensional array. Planar scans are performed for each aperture location. The apertures are counter rotated (i.e., one clockwise and the other counter clockwise).

Abstract: The present invention relates to a method for examining a medium (19), comprising the following steps of: transmitting a measurement input signal (4) comprising at least one measurement frequency, wherein the measurement input signal (4) is coupled into a medium (19); receiving a measurement output signal (9) emerging from the medium (9); transmitting a counter measurement input signal (13) comprising at least one counter measurement frequency, wherein the counter measurement frequency essentially corresponds to the measurement frequency, and wherein the counter measurement input signal (13) is coupled into the medium (19) simultaneously and in an opposite direction to the measurement input signal (4); receiving a counter measurement output signal (16) emerging from the medium (19); calculating a Doppler correction by comparing the counter measurement input signal (13) with the counter measurement output signal (16) in terms of the counter measurement frequency and by comparing the measurement input signal (4

Abstract: An exploration operation, in which the transmission/reception position, at which ultrasonic waves are transmitted and received, is changed by a specified pitch distance, is performed for each of a plurality of incident angles. A nonlinear image in which echo signals acquired from harmonic waves of reflected waves are presented is generated for each incident angle. Each nonlinear image is converted into a frame conversion image in accordance with the cross-sectional shape of an exploration-target area. A signal intensity threshold for removing echo signals resulting from an orientation defect is determined in advance. Frame conversion images formed by only echo signals 41a whose signal intensity is the signal intensity threshold or more are overlapped to generate a nonlinear exploration image 35. Exploration of a welded portion 23 stably provides a nonlinear exploration image 35 in which the shape of an interface 25 of the welded portion 23 is shown accurately and clearly.

Abstract: Provided is a 2-dimensional virtual array probe for 3-dimensional ultrasonic imaging. The probe includes: an ultrasonic transducer; a metallic probe body including an ultrasonic wave emission surface in which a plurality of wave-guides are arranged in 2-dimensional array and a ? sphere-shaped recess for irregularly reflecting ultrasonic wave emitted from the ultrasonic transducer in an inside thereof; a piezoelectric sheet arranged on the ultrasonic wave emission surface to make contact with an object to be inspected and configured to pass the ultrasonic waves emitted from the probe toward the object to be inspected and output a signal by detecting the ultrasonic waves reflected from the object to be detected; and a control unit configured to control the ultrasonic transducer so that the plurality of wave-guides sequentially generate ultrasonic wave.

Abstract: A probe for use with an imaging system, including a scanning device configured to receive a first light beam from a light source, a beam-divider configured to split the first light beam into a plurality of second light beams, and a focusing device configured to focus each of the second light beams on respective locations in an object of interest.

Abstract: Systems and methods are disclosed for improving the resolution and quality of an image formed by signals from an array of receivers. Multiple receivers introduce variations in arrival times that can be less than the period of an operating signal, and also less than the period associated with a sampling operation. Thus, multiple receivers allow sampling of fine features of reflected signals that would be considered beyond the resolution associated with the operating signal. Use of multiple receivers also provides an effective sampling rate that is greater than the sampling rate of an individual receiver. Similar advantages can be obtained using multiple transmitters. Such advantageous features can be used to obtain high resolution images of objects in a medium in applications such as ultrasound imaging. Sub-Nyquist sampling is discussed. Accounting for the effects of refraction on pathlengths as a signal passes between two regions of different sound speed allows improved calculation of focus distances.

Abstract: A quantitative evaluation device and method of an atomic vacancy, which are capable of efficiently and quantitatively evaluating an atomic vacancy existing in a silicon wafer. A quantitative evaluation device 1 is equipped with a detector 5 including an ultrasonic generator 27 and an ultrasonic receiver 28, a silicon sample 6 formed with the ultrasonic generator 27 and the ultrasonic receiver 28 on a silicon wafer 26 comprising perfect crystal silicon, a magnetic force generator 4 for applying an external magnetic field to the silicon sample 6, and a cooler 3 capable of cooling and controlling the silicon sample 6 to a range of temperatures lower than or equal to 50K.

Abstract: Ultrasonic inspection equipment facilitates alignment of display positions of three-dimensional ultrasonic inspection data and three-dimensional shape data, and quickly discriminates between a defect echo and an inner-wall echo. A computer 102A has a position correction function of correcting a relative display position between three-dimensional shape data and three-dimensional ultrasonic inspection data. A display position of the three-dimensional ultrasonic inspection data or that of the three-dimensional shape data is moved by a norm of a mean vector along the mean vector that is calculated from a plurality of vectors defined by a plurality of points selected in the three-dimensional ultrasonic inspection data and by a plurality of points selected in the three-dimensional shape data. The three-dimensional shape data and the three-dimensional ultrasonic inspection data are displayed in such a manner as to be superimposed on each other on a three-dimensional display unit 103C.

Abstract: A scanning acoustic microscope comprises a structure including a loading portion and a scanning portion, a transducer disposed in the scanning portion and operable to develop ultrasonic energy, and a controller. A driver is responsive to the controller and is capable of moving the transducer along a scan path with respect to a first plurality of parts disposed in the scanning portion as a second plurality of parts are being loaded into the loading portion.

Abstract: A scanning acoustic microscope includes a transducer mounted in a cup below a particular elevation and a coupling fluid source disposed below the particular elevation and which is adapted to introduce coupling fluid into the cup. A controller is operable to control the transducer and the coupling fluid source during testing such that ultrasonic energy can be directed upwardly through coupling fluid disposed between and contacting the transducer and a first surface of a part to be inspected.

Abstract: A method for monitoring a system, in which a plurality of acoustic images are recorded and compared at defined intervals of time over a period of time extending several weeks. A large system can be monitored reliably and with little complexity if the acoustic images each contain a plurality of acoustic image areas which are arranged in a spatially different manner, and, between respective recordings of the image areas of an acoustic image, an acoustic sensor is aligned with an image area, which is to be recorded, of a next image area by being moved.

Abstract: A transmission probe and a reception probe for transmitting and receiving a wideband ultrasonic wave are provided. Each time when the locations of the probes and are moved, a received wave Gj(t) is obtained. Based on a spectrum Fj(f) corresponding to the received wave Gj(t), a narrowband spectrum FAj(f) is extracted. A component wave GAj(t) corresponding to the narrowband spectrum FAj(f) is found by inverse Fourier transformation. A longitudinal wave primary resonance frequency f1 having a relationship with a thickness W (mm) of an inspection target and a primary resonance frequency fS1 of a transverse wave generated by mode conversion are calculated. A comparative display of the component waves GAj(t) is presented using f1, fS1 and sizing coefficients ns1, ns2, ns3 and ns4 for high precision inspection.

Abstract: In one embodiment, a system to characterize an anomaly in a laminate structure comprises a plurality of actuators to generate a wave signal into a structure being evaluated, a plurality of sensors to collect scattered wave data caused by energy of the wave signal being at least partially reflected or scattered by an anomaly, and a structural health monitoring unit. In some embodiments the structural health monitoring unit executes a scatter imaging algorithm to generate three dimensional image data for the anomaly from the scattered wave data, extracts a scatter volume from the from the scattered wave data, and generates a damage volume estimate and a damage depth estimate from the scattered wave data. Other embodiments may be described.

Abstract: Scanning probe microscopes include a probe tip coupled to a tuning fork or other acoustic resonator so as to apply a shear force when contacted to a specimen surface based on an applied acoustic signal. A secondary ultrasonic transducer is in acoustic communication with the specimen and a resonant structure. Probe tip-specimen displacement can be detected based on whispering gallery mode ultrasonic waves in the resonant structure using the secondary transducer, and such displacements maintained using feedback control based on whispering gallery mode acoustic wave magnitude.

Abstract: The present invention relates to a method for generating mechanical waves within a viscoelastic medium (11) comprising a step of generating an acoustic radiation force (15) within the viscoelastic medium (11) by application of acoustic waves focused on an interface (13) delimiting two zones (11, 14) having distinct acoustic properties.

Abstract: There is provided a quantitative evaluation device or the like of atomic vacancy existing in a silicon wafer in which the atomic vacancy concentration in the silicon wafer can be quantitatively evaluated by forming a rationalized thin-film transducer on a surface of a silicon sample without conducting an acceleration treatment for enhancing the concentration.

Abstract: The present invention relates to an ultrasound diagnostic system. The ultrasound diagnostic system includes a plurality of connectors. Each of the connectors has a signal transmitter to transmit an identification signal uniquely identifying the respective connector. The ultrasound diagnostic system further includes a plurality of probes. Each of the probes has a signal detector and an indicator assembly. In response to a connection of each of the probes to one of the connectors, the signal detector of the respective probe is configured to detect the identification signal identifying said one of the connectors and the indicator assembly of the respective probe is configured to provide an identification of said one of the connectors based on the identification signal.

Abstract: A method for generating an image of an anomaly may include generating a pulse wave into a structure being evaluated from each of a plurality of sensors and collecting any scattered wave data caused by the pulse wave impacting an anomaly. The scattered wave data may be collected by the same sensor that generated the pulse wave or by a different sensor. The method may also include identifying any backscattered wave data from a distal edge or border of any anomaly relative to a location of the sensor collecting the scattered wave data. The method may additionally include processing the backscattered wave data from each of the sensors collecting the scattered wave data to generate a two dimensional image of any anomaly. The method may further include presenting the two dimensional image of any anomaly.

Abstract: Imaging devices for measuring a structure of a surface and methods of use are provided. In certain embodiments, an imaging device includes at least one nano-mechanical resonator pair. The pair includes a reference resonator having a reference resonant frequency, and a sense resonator having a first sense resonant frequency. The device is configured to expose the sense resonator to the surface such that the sense resonator has a second sense resonant frequency. The device is also configured to measure the structure of the surface based on a difference between the second sense resonant frequency and the reference resonant frequency. In certain embodiments, an imaging device for measuring the structure of a surface includes an array of sense nano-electromechanical resonators. In certain embodiments, the array of single nano-electromechanical resonators is advantageously arranged in a staggered configuration.

Abstract: A method for conducting nondestructive internal inspection of a rotary drill bit used for drilling subterranean formations comprises communicating ultrasonic waves into a drill bit and detecting ultrasonic waves that are reflected by at least a portion of the drill bit. In some embodiments, the waves may be directed into the drill bit from within a longitudinal bore thereof. Reflected waves also may be detected from within the bore. The methods may be used to develop threshold acceptance criteria for classifying drill bits as acceptable or unacceptable to prevent catastrophic failures of drill bits during use. Systems and apparatuses are disclosed for conducting nondestructive ultrasonic inspection of a drill bit used for drilling subterranean formations. The systems and apparatuses may comprise an ultrasonic probe configured for insertion within an internal longitudinal bore of a drill bit. Drill bits are disclosed that are configured to facilitate nondestructive ultrasonic inspection thereof.

Abstract: The invention provides CTGF which is associated with the cardiovascular diseases and hematological diseases. The invention also provides assays for the identification of compounds useful in the treatment or prevention of cardiovascular diseases and hematological diseases. The invention also features compounds which bind to and/or activate or inhibit the activity of CTGF as well as pharmaceutical compositions comprising such compounds.

Abstract: An imaging device, is provided, comprising: a plurality of compression circuits configured to receive K initial imaging signals and to generate second through Kth modified imaging signals, and a plurality of delay values; and a bit multiplexer configured to generate a compressed bit stream based on a first imaging signal, second through Kth modified imaging signals, and the delay values, each compression circuit including: a delay computer configured to determine a delay value by comparing two adjacent initial imaging signals, a delay circuit configured to delay a first of the two adjacent imaging signals by the delay value to generate a delayed imaging signal; a subtractor configured to subtract the delayed signal from a second of the two adjacent imaging signals to generate a reduced imaging signal; and a quantizer configured to generate a quantized imaging signal corresponding to the second of the two adjacent imaging signals.

Abstract: A method for the non-destructive inspection of a test body using ultrasound is disclosed, in which at least one ultrasonic transducer couples ultrasonic waves into the test body and ultrasonic waves reflected inside the test body are received by ultrasonic transducers and converted into ultrasonic signals, which form the basis of the non-destructive inspection.

Abstract: An optical-acoustic transducer structure includes at least one metal or semiconducting film in which a part of a pump light pulse is absorbed to generate a sound pulse; and at least one dielectric film. The thicknesses and optical properties of the at least one metal or semiconducting film and the at least one dielectric film are selected so that a returning sound pulse results in a measurable change in the optical reflectivity and/or some other optical characteristic of the transducer structure. The transducer structure includes a resonant cavity, and an output surface that is shaped so as to provide no significant focusing of generated sound waves when the sound waves are launched towards a surface of the sample.

Abstract: An ultrasonic diagnostic apparatus that performs high acoustic pressure and low acoustic pressure ultrasonic transmissions by switching at predetermined timing in the enhanced ultrasonography, and displays concurrently a replenishment image obtained through the low acoustic pressure transmission in real time like a moving picture, and a pre-flash image obtained through the low acoustic pressure transmission immediately before switching to the high acoustic pressure transmission like a still image to allow the operator to understand the structure at the level of capillaries. It is also possible to display a selected image obtained through the low acoustic pressure transmission at an arbitrary timing instead of the pre-flash image.

Abstract: An ultrasonic inspection apparatus includes a container containing de-ionized water, at least one limiting member, a loading member, and a cover member. The at least one limiting member, the loading member, and the cover member are disposed in the de-ionized water and between the transmitting transducer and the receiving transducer. The limiting member is supported on the limiting member for loading the integrated circuits to be inspected. The cover member is detachably disposed on the loading member for holding the integrated circuits by a gravitational force of the cover member acting on the loading member.

Abstract: A plane or volume is scanned with ultrasound. Electronic movement of apertures is used during the scanning. Scanning with the apertures is interleaved. The apertures move along the array in opposite directions, preventing or limiting large temporal discontinuity. For example, two apertures begin at similar angles on a two-dimensional array. Planar scans are performed for each aperture location. The apertures are counter rotated (i.e., one clockwise and the other counter clockwise).

Abstract: An ultrasonic test apparatus includes a container containing de-ionized water, a pressing member, a supporting member, and a fixing member. The limiting member, the loading member, and the cover member are disposed in the de-ionized water. The fixing member tightly fixes the pressing member and the supporting member together for mounting at least part of integrated circuits to be detected between the pressing member and the supporting member.

Abstract: The present invention relates to a method of acquiring an ultrasound image in an ultrasound imaging system having an array transducer, comprising: a) setting an image point at a predetermined depth on an ultrasound image acquired based on a reference speed of sound for a target object; b) setting a range of speed of sound with reference to the reference speed; c) setting a plurality of speeds of sound in a predetermined interval within the range of speed of sound; d) acquiring ultrasound images at each speed of sound; e) calculating an amplitude of an image point set at a predetermined depth of each ultrasound image; f) determining a real speed of sound in the target object based on the calculated amplitude; and g) acquiring an ultrasound image based on the determined real speed of sound in the target object.

Abstract: The present invention relates to a method for examining a medium (19), comprising the following steps of: transmitting a measurement input signal (4) comprising at least one measurement frequency, wherein the measurement input signal (4) is coupled into a medium (19); receiving a measurement output signal (9) emerging from the medium (9); transmitting a counter measurement input signal (13) comprising at least one counter measurement frequency, wherein the counter measurement frequency essentially corresponds to the measurement frequency, and wherein the counter measurement input signal (13) is coupled into the medium (19) simultaneously and in an opposite direction to the measurement input signal (4); receiving a counter measurement output signal (16) emerging from the medium (19); calculating a Doppler correction by comparing the counter measurement input signal (13) with the counter measurement output signal (16) in terms of the counter measurement frequency and by comparing the measurement input signal

Abstract: Apparatus for Scanning Acoustic Microscopy (SAM) of a semiconductor device including a substrate with an acoustic probe, The substrate has upper and lower surfaces. A sealed lower space provides an environment surrounding the lower surface. An upper ring structure formed above the upper surface includes an upper sealing ring in contact with the upper surface, with the upper sealing structure and the seal forming a dam for retaining the acoustic transmission fluid above the upper surface. A fixture base retains a lower sealing ring in contact with the lower surface surrounding the lower surface. An acoustic scanning probe positioned confronting the upper surface of the semiconductor device extending into the acoustic transmission fluid retained in contact with the upper surface.

Abstract: An ultrasonic imaging device, comprising: a receiver, for receiving ultrasonic signals which carry information about human body; a processor, for analyzing and processing the received ultrasonic signals in order to get image and/or sound signals; a controller, for issuing at least one instruction; and a recorder, for recording the image and/or sound signals on recording medium in digital form in accordance with the instruction.

Abstract: An acoustic transducer has a first transducer which transmits an acoustic primary wave having two frequency components, and a second transducer which, in order to receive a reflected wave of an acoustic secondary wave generated with propagation of the acoustic primary wave, is disposed so that a region for receiving the reflected wave is superimposed on the first transducer as seen along the direction of transmission of the acoustic primary wave.

Abstract: An ultrasonic transducer is provided with a distance measuring ultrasonic sensor for detecting a distance between the ultrasonic transducer and a surface of an inspection object and an inclination of the ultrasonic transducer with respect to the surface of the inspection object, to control the distance and the inclination of the ultrasonic transducer with respect to the inspection object based on information detected by the distance measuring ultrasonic sensor, and at least part of ultrasonic wave transmission/reception by the distance measuring ultrasonic sensor is performed during execution of aperture synthesis processing during which transmission/reception by the ultrasonic transducer is not performed.

Abstract: An ultrasonic imaging system wherein an exemplary system includes an array of transducer elements arranged along a first plane for transmitting first signals and receiving reflected signals for image processing. Circuit structures each have a major surface positioned in a co-planar orientation with respect to a major surface of another of the circuit structures to provide a sequence of the structures in a stack-like formation. Electrical connections are formed between adjacent circuit structures in the sequence. A connector region on each circuit structure includes a distal portion extending away from the major surface-with distal portions of connector regions of adjacent structures spaced apart from one another. A first wiring pattern extends from the major surface to the distal portion of the connector region.

Abstract: Disclosed is an ultrasonic lens configuration permitting the production of an acoustic field from low frequency ultrasound waves with predictable regions of energy concentration. The lens comprises at least three adjacent convex surface contours. Each surface contour corresponds to an arc of an ellipse. The first surface contour is within the center of the lens and is flanked by two adjacent contours. The flanking contours correspond to arcs from two symmetrical ellipses having semi-latus rectums at least equal to the semi-latus rectum of the ellipse to which the first, central, contour corresponds. The contours of the lens are arranged such that the flanking contours extend past the first contour by positioning the contours so that if the ellipses to which they correspond were drawn the ellipses of the flanking contours directly adjacent to the first contour would have their centers aligned on a plane parallel to and not below the major or minor axis of the ellipse of the first contour.

Abstract: The present invention relates to an ultrasonic probe for producing a real-time three dimensional live action image (a four dimensional image), which has a long lifetime, and an improved image quality, can prevent malfunction.