Ultrasound transducer

Last revised by Craig Hacking on 8 Feb 2024

Citation, DOI, disclosures and article data

Citation:

Nightingale R, Hacking C, Murphy A, et al. Ultrasound transducer. Reference article, Radiopaedia.org (Accessed on 16 Apr 2024) https://doi.org/10.53347/rID-54038

DOI:

https://doi.org/10.53347/rID-54038

Permalink:

https://radiopaedia.org/articles/54038

rID:

54038

Article created:

21 Jun 2017, Rachael Nightingale

Disclosures:

At the time the article was created Rachael Nightingale had no recorded disclosures.

View Rachael Nightingale's current disclosures

Last revised:

8 Feb 2024, Craig Hacking ◉ ◈

Disclosures:

At the time the article was last revised Craig Hacking had the following disclosures:

Philips Australia, Paid speaker at Philips Spectral CT events (ongoing)

These were assessed during peer review and were determined to not be relevant to the changes that were made.

View Craig Hacking's current disclosures

Revisions:

20 times, by 9 contributors - see full revision history and disclosures

Sections:

Imaging Technology

Tags:

refs, cases

Synonyms:

Transducer
Transducers
Ultrasound transducers

An ultrasound transducer converts electrical energy into mechanical (sound) energy and back again, based on the piezoelectric effect. It is the hand-held part of the ultrasound machine that is responsible for the production and detection of ultrasound waves.

Components

A transducer consists of five main components:

crystal/ceramic element with piezoelectric properties
- usually lead zirconate titanate (PbZT) ³
- may consist of a single element or be a broadband transducer with multiple elements
- piezoelectric polyvinylidene fluoride (PVDF) is useful in those high frequency, high bandwidth transducer that needs focusing to a certain region ⁴. PVDF also has low acoustic impedance similar to water, thus is useful in making ultrasound pulses with good temporal resolution ⁵.
- element thickness is determined by what resonance frequency is desired
  - equal to half the wavelength ³
  - a thicker element produces a lower frequency oscillation while a thinner element produces a higher frequency oscillation ³
positive and ground electrodes on the faces of the element
- this allows for electrical connection
- positive electrode is in the back of the element ³
- ground electrode is on the front of the element ³
damping (backing) block
- adhered to the back of the crystal (behind the positive electrode) ³
- absorbs ultrasound energy directed backward and attenuates stray ultrasound signals from the housing ¹
- dampens the resonant vibrations in the element which creates a shorter spatial pulse length ³; this allows for better axial resolution for imaging of organs and high bandwidth to receive reflected echoes ³.
matching layer
- interface between the transducer element and the tissue ³
- allows close to 100% transmission of the ultrasound from the element into the tissues by minimizing reflection due to traversing different mediums (acoustic impedance) ²
- achieves this by consisting of layers of material with acoustic impedances that are between soft tissue and transducer material.
  - may consist of one or multiple layers
- each layer is one-quarter wavelength thick ³
housing
- electrical insulation and protection of the element ³
- includes a plastic case, metal shield and acoustic insulator

Ultrasound beam production

Ultrasound transducers typically consist of 128-512 piezoelectric elements arranged in linear or curvilinear arrays. Each element is individually insulated.

Transducers can produce an ultrasound beam by mechanical or electronic means. In mechanical transducers, either oscillating or rotating wheels is used. In electronic transducers, there are two ways to generate ultrasound beam ³:

linear array (also called sequential array)
phased array

As a general rule, if the shape at the top of the images matches the shape at the bottom of the image it is a sequential array. If the shapes are different (e.g. rectangular at the top and curved at the bottom) it is a phased array.