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Piezoelectric Effect Sound waves striking a PZ material produce an electrical signal Can be used to detect sound (and echoes)!
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Piezoelectric Effect Sound waves striking a PZ material produce an electrical signal Can be used to detect sound (and echoes)!
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Reverse Piezoelectric Effect Applying an electrical signal causes the PZ element to vibrate Produces a sound wave
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Transducer Define? Many types of transducers exist –Pressure transducers –Air flow transducers, etc. What is function of transducer? convert electrical signals to sound waves, and vice versa.
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Ultrasound Transducer Materials Quartz (naturally piezoelectric) –First used as a stable resonator in time measurement devices –Used in some laboratory ultrasound applications Most current applications use piezoelectric ceramics (ie, lead zirconate titanate; barium titanate) –Lower “Q” (good for short pulses) –Good sensitivity –Many shapes are possible Miniature quartz tuning fork; 32,768 Hz.
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Polarizing a Piezoelectric Element Most ultrasound transducer materials are not ‘naturally’ piezoelectric –Lead zirconate titanate –Microscopic crystals, randomly oriented Must be polarized –Heat to ~350 o C (Curie Temperature) –Apply strong voltage across crystal –Cool while voltage is still applied
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Polarization
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Single Element Transducers Uses –Simple A-mode machines –Mechanical scanning transducers The design serves as a useful example of general construction methods
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Single element transducer construction
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Ultrasound Transducers Piezoelectric (PZT) ceramic elements Matching layers, lens Backing layer
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½ wavelength resonance Resonance frequency corresponds to the thickness = ½ wavelength Speed of sound in Piezoelectric material ~ 4,620 m/s What thickness is required for a 3 MHz frequency transducer? d
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½ wavelength resonance Resonance frequency corresponds to the thickness = ½ wavelength Speed of sound in Piezoelectric material ~ 4,620 m/s What thickness is required for a 3 MHz frequency transducer? d
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½ wavelength resonance Resonance frequency corresponds to the thickness = ½ wavelength Speed of sound in Piezoelectric material ~ 4,620 m/s What thickness is required for a 5 MHz frequency transducer? d
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Resonance Frequency
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Backing (Damping) Layer Need short duration pulses for decent axial resolution (we will discuss this later) Backing layer helps to reduce vibrations of the element following excitation –Like placing your hand on a bell to stop the ringing!
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Matching Layers Thin layer of material –¼ wavelength thick –Impedance is between that of the element (quite high) and that of tissue Provides better sound transmission from the transducer-patient-transducer Improves sensitivity
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Focusing, Methods Focusing reduces the beam width in the focal zone Methods –Lens –Curved element –Electronic
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2.5 MHz 20 mm 5.0 MHz In Most Applications, Beams Are Focused - curved element - lens - electronic (arrays) Improves lateral resolution near the focal distance Higher frequencies produce narrower beams Dr.Awad Elkhadir
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2.5 MHz 10 mm 20 mm 5.0 MHz - Previous diagrams exhibit sidelobes - Must be eliminated for good image quality - Pulsing reduces (or even eliminates) side lobes 5.0 MHz CW Short pulse (50% bw)
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Array Transducer “Scanhead” containing many small PZT elements Element, along with a transmit-receive circuit in the machine is a channel. 128 channels are common.
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Beam Forming (Transmit) Group also permits electronic beam steering and electronic focusing.
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Curvilinear
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Phased Array
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Linear-Phased ( “Virtual Convex”) Linear array –Rectangular FOV, defined by transducer footprint VC adds beam steering to expand imaged region at edges
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Annular
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