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Ultrasound Probe
NDK has a wide range of probe portfolio for many applications.
The certification of "ISO13485:2016"
that is International Standard of the quality management system
in medical devices acquired, and we will deliver secure,
safe and high-quality product for medical devices.
Custom Design
We can provide customized probes according to customer's request(OEM).
■Custom-made specification are available
(Frequency, Element Pitch, Element Length, Product Shape etc)
Search Ultrasound Probe (Transducer)
※Specifications are subject to change or discontinuated without notice.
Search by Probe Type
Product for 2D Imaging
| Probe Type | Feature | Application | Central Frequency |
Element | Radius of Curvature |
Main Product | |
|---|---|---|---|---|---|---|---|
 Linear Type |
Wide footprint and keep same field of view at deep part. |
|
2.5MHz | 15MHz |
64ch | 256ch |
- | 7.5MHz Linear |
Array Module |
| Probe |
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10MHz Linear |
Array Module |
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| Probe |
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13MHz Linear |
Array Module |
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| Probe |
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15MHz Linear |
Array Module |
||||||
 Convex(Curved) Type |
Wide footprint, field of view will be spreaded at deep part. |
|
2.5MHz | 7.5MHz |
64ch | 192ch |
R10 | R80 |
3.5MHz Convex (Curved) |
Array Module |
| Probe |
|||||||
3.5MHz Convex (Curved) (Single Crystal) |
Array Module |
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| Probe |
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7MHz Convex (Curved) |
Array Module |
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 Phased(Sector) Type |
Small footprint, field of view will be spreaded widely at deep part. |
|
2MHz | 7.5MHz |
32ch | 128ch |
- | 2.5MHz Phased (Sector) |
Array Module |
| Probe |
|||||||
 Single Type |
A) The measurement of distance. B) B mode scanning by |
|
2MHz | 22MHz |
- | - | ||
20MHz Single Type |
Array Module | ||||||
Product for 3D Imaging
| Probe Type | Feature | Application | Central Frequency |
Element | Radius of Curvature |
Main Product | |
|---|---|---|---|---|---|---|---|
 Linear Type |
Real time 3D probe with the linear scanning type. |
|
7.5MHz | 11MHz |
128ch | 192ch |
- | Mechanical Scanning 3D 8MHz Linear |
|
 Convex(Curved) Type |
Real time 3D probe with the wide field of view. |
|
3.5MHz | 6.5MHz |
128ch | 192ch |
<R40 | R48 |
Mechanical Scanning 3D 4.5MHz Convex (Curved) |
|
Search by Inspection Area ※Besides the examples of diagnosis shown below, ultrasound probe are also used for many other different diagnostic applications.
Abdomen
Ultrasound probe are used for diagnosis of internal organs including liver, kidneys,
pancreas and gallbladder or watching fetal growth and health condition in the maternal body.
Probe for Abdomen
Array Module
| Central Frequency |
Element | Radius of Curvature |
Probe Type |
|---|---|---|---|
| 2.5MHz | 7.5MHz |
64ch | 192ch |
R10 | R60 |
Convex (Curved) Type |
Sample Data
Probe
| Central Frequency |
Element | Radius of Curvature |
Probe Type |
|---|---|---|---|
| 3.5MHz | 7.0MHz |
64ch | 192ch |
R40 | R60 |
Convex (Curved) Type |
Sample Data
Mechanical
Scanning 3D Probe
| Central Frequency |
Element | Radius of Curvature |
Probe Type |
|---|---|---|---|
| 3.5MHz | 4.5MHz |
128ch | 192ch |
R40 | R48 |
Convex (Curved) Type |
Sample Data
Mechanical Scan for 3D Imaging
Mechanically moving the electronic scanning convex type probe over the abdomen of a pregnant woman
in a fan shape will acquire 3D data to produce images. The moving speed and angle can be adjusted to
acquire 3D image data suitable for your purpose of use.
From the 3D data, it is possible to obtain cross-section images at any given point of the axis (horizontal plane)
perpendicular to the direction of propagation of Ultrasound waves from the probe that cannot be viewed in
traditional 4D images. This provides even wider information for diagnosis.
Mammary Grand・Thyroid Gland
Ultrasound probe are used for breast cancer check-ups to detect the presence of lumps under breasts or any
changes in their shape, and for thyroid gland examinations to detect the presence of lumps inside the neck.
Probe for Mammary Grand and Thyroid Gland
Array Module
| Central Frequency |
Element | Radius of Curvature |
Probe Type |
|---|---|---|---|
| 7MHz | 13MHz |
64ch | 256ch |
- | Linear Type |
Sample Data
Probe
| Central Frequency |
Element | Radius of Curvature |
Probe Type |
|---|---|---|---|
| 7MHz | 12MHz |
64ch | 192ch |
- | Linear Type |
Sample Data
Mechanical
Scanning 3D Probe
| Central Frequency |
Element | Radius of Curvature |
Probe Type |
|---|---|---|---|
| 7.5MHz | 11MHz |
128ch | 192ch |
- | Linear Type |
Sample Data
Parallel Scan
This linear type uses the world's first "parallel scan" technology that allows the built-in probe to directly move
in a lateral direction (reciprocal scan) with a motor.
Compared to the traditional arc scanning, this parallel scanning provides higher lateral resolution of diagnostic images.
The probe also has a flat surface that touches the target part of the human body (the surface that sends and receives ultrasound waves). This geometry allows the probe to ensure more uniform contact with the irregular surface of breasts and other parts of the human body.
Circulatory Organ
Ultrasound plobe are used for cardiac diagnosis to capture the size of the heart and to check it for shape or
movement abnormality as well as to determine the heart blood flow condition.
Probe for Circulatory Organ
Array Module
| Central Frequency |
Element | Radius of Curvature |
Probe Type |
|---|---|---|---|
| 2MHz | 7.5MHz |
32ch | 128ch |
- | Phased (Sector) Type |
Sample Data
Probe
| Central Frequency |
Element | Radius of Curvature |
Probe Type |
|---|---|---|---|
| 2MHz | 7.5MHz |
32ch | 128ch |
- | Phased (Sector) Type |
Sample Data
Transvaginal・Transrectal
Ultrasound plobe are used for uterus examinations to detect any variation in the contour of the uterus or the
presence of uterine myoma as well as for prostate examinations.
Probe for Transvaginal and Transrectal
Array Module
| Central Frequency |
Element | Radius of Curvature |
Probe Type |
|---|---|---|---|
| 6MHz | 7MHz |
64ch | 128ch |
R10 | Convex (Curved) Type |
Sample Data
Probe
| Central Frequency |
Element | Radius of Curvature |
Probe Type |
|---|---|---|---|
| 6MHz | 128ch | 192ch |
R10 | TV Type |
Blood Vessel
Ultrasound Probe are used to check the blood vessels for an abnormal wall (vascular intimal)
condition or blood flow, helping detection of hardening of the arteries.
Probe for Blood Vessel
Array Module
| Central Frequency |
Element | Radius of Curvature |
Probe Type |
|---|---|---|---|
| 7.5MHz | 15MHz |
64ch | 256ch |
- | Linear Type |
Sample Data
Probe
| Central Frequency |
Element | Radius of Curvature |
Probe Type |
|---|---|---|---|
| 7.5MHz | 13MHz |
128ch | 192ch |
- | Linear Type |
Sample Data
Axial Length
Ultrasound probe are used for close examination of
eyes prior to ophthalmic operations such as cataract treatments.
Probe for Axial Length Inspection
| Central Frequency |
Element | Radius of Curvature |
Probe Type |
|---|---|---|---|
| 10MHz | 22MHz |
- | - | Single Type |
Sample Data
Frequency and Resolution
High frequency probe can get the fine imaging with good resolution.
However the imaging of deep part will be smudgy due to wave length is short.
Meanwhile the imaging resolution of low frequency probe is low but ultrasound wave can reach deep part.
The scanning depth and resolution are mainly determined by the frequency of probe.
| Frequency | Resolution | Penetration | Possible Scanning Depth |
|---|---|---|---|
| High | Fine | Weak | Shallow |
| Low | Rough | Strong | Deep |
The Basic Principle of Ultrasound Probe
The ultrasound probe consists of a piezoelectric element (transducer), backing material, an acoustic matching layer and an acoustic lens. The following describes the components and their functions of the convex type probe as an example.
NDK, as a crystal device manufacturer, applies its proprietary technologies to the probe manufacturing processes, such as micromachining of piezoelectric elements and installation of acoustic matching layers.
◀︎
▶︎
The piezoelectric element is an essential part of the probe to generate ultrasound waves.
On both sides of the piezoelectric element electrodes are affixed and a voltage is applied.
The element then oscillates by repeatedly expanding and contracting, generating a sound wave. When the element is externally applied with oscillation (or an ultrasound wave) in turn, it generates a voltage.
Among the several types of piezoelectric elements, piezoelectric ceramic (PZT: lead zirconate titanate) is most commonly used because of its high conversion efficiency.
The piezoelectric element is divided into strip sections, which are each affixed with electrodes.
Each strip section of the piezoelectric element has a width about a half of that of a piece of hair.
The process to cut the element into sections in micron order and affix them is based on the high-level technology of NDK.
The backing material is located behind the piezoelectric element to prevent excessive oscillation.
Reducing excessing oscillation will cause the element to generate ultrasound waves with a shorter pulse length, contributing to the higher resolution in determining the distance to objects in images.
Ultrasound waves transmitted from the probe are reflected off a target because there is a big difference in acoustic impedance between the piezoelectric element and the object. To avoid this phenomenon, an intermediate material is inserted between the two so that ultrasound waves can efficiently enter the object. This is the role of the acoustic matching layer.
This acoustic matching for less reflection of ultrasound waves makes it possible to implement highly sensitive probes.
The acoustic matching layer uses a combination of different resin materials to obtain an adequate acoustic impedance value, ensuring acoustic matching.
The acoustic lens is a gray part looking like rubber attached to the tip of the probe. Without the acoustic lens, ultrasonund waves transmitted from the probe would spread and travel like light. The acoustic lens prevents the ultrasound waves from spreading and focuses them in the slice direction to improve the resolution.
Frequently Asked Questions
Don't ultrasound waves scatter?
The likeliness of scattering of ultrasound waves depends on the size of the sound source and the frequency (wavelength).
In general, ultrasound waves transmitted from a smaller source are more likely to scatter and those from a larger source less likely to scatter.
Attaching an acoustic lens to the ultrasound probe will allow the probe to focus ultrasonic waves.
To what extent can the lens focus ultrasound waves?
The focusing effect of an acoustic lens depends on the near field length that is decided by the size of the ultrasound sensor and the wavelength (radius of the transducer/wavelength) and the curvature of the lens.
Which part of the sensor uses crystals?
None of the modern ultrasound sensors mainly used for medicine use crystals.
Because of their low electromechanical coupling factor, crystals are not suitable for use in transducers that convert electric signals into ultrasound waves (and vice versa) such as ultrasound sensors.
Instead, ceramic materials are typically used in piezoelectric elements.
How are transducers driven?
When a pulse voltage is applied across the electrodes attached to both poles of the piezoelectric element, the element has mechanical oscillation with its own resonance frequency.
For more information, see "Basic Knowledge: Basic Principle of Operation of Medical Ultrasound Probes".
How can 3D images be obtained?
3D images can be generated when data in the three-axis directions to the sensor (longitudinal, lateral and depth) are available.
NDK uses the technology that mechanically moves a cross-sectional probe capable of obtaining lateral and depth data in the longitudinal direction to implement 3D imaging.
Abdomen probes are mainly used as 3D imaging sensors for prenatal diagnosis.
