Oluschinski: Created page with "{{Language_sel|LANG=ger|ARTIKEL=HF-Bild}} {{PSM_Infobox}} HF-scan FORCETOC ==Fundamentals== A simple imaging evaluation method for ultrasound testing is the HF-scan of an ultrasonic signal emitted by the measuring device itself ('''Figure'''). It corresponds to the movements of volume elements of the transducer in the time domain. Normally, the ultrasonic sensor ou..."

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Created page with "{{Language_sel|LANG=ger|ARTIKEL=HF-Bild}} {{PSM_Infobox}} <span style="font-size:1.2em;font-weight:bold;">HF-scan </span> __FORCETOC__ ==Fundamentals== A simple imaging evaluation method for ultrasound testing is the HF-scan of an ultrasonic signal emitted by the measuring device itself ('''Figure'''). It corresponds to the movements of volume elements of the transducer in the time domain. Normally, the ultrasonic sensor ou..."

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{{Language_sel|LANG=ger|ARTIKEL=HF-Bild}}
{{PSM_Infobox}}
<span style="font-size:1.2em;font-weight:bold;">HF-scan </span>
__FORCETOC__

==Fundamentals==

A simple imaging evaluation method for [[Ultrasound Testing|ultrasound testing]] is the HF-scan of an ultrasonic signal emitted by the measuring device itself ('''Figure'''). It corresponds to the movements of volume elements of the transducer in the time domain. Normally, the [[Ultrasonic Sensors|ultrasonic sensor]] outputs a voltage signal in units of volts, which is plotted over time. For better handling, the voltage signal is often scaled logarithmically.

[[File:HF-Scan.jpg|450px]]
{|
|- valign="top"
|width="50px"|'''Figure''':
|width="600px" |Example of an HF-signal with logarithmic scaling from an ultrasonic measurement on aluminium with a wall thickness of 9 mm
|}

==Practical relevance==

The HF-scan can be used to determine the runtime and amplitude ratios. If the [[Sound Velocity|sound velocity]] is known, the [[Ultrasonic Wall Thickness Measurement|wall thickness]] or fault depth can be determined. In principle, it is also possible to calculate the specific attenuation. Furthermore, signal filtering can be performed, allowing selective signal analysis. Signal filtering is based on Fourier analysis (see also: [[Frequency Analysis|frequency analysis]]), whereby areas of no interest are cut out of the frequency spectrum. A reverse transformation is then performed, resulting in the filtered voltage signal, e.g. cleaned of interference or noise signals. This process is called signal convolution. If upper and lower frequencies are cut out, i.e. a high-pass and low-pass filter is applied, this is referred to as bandpass filtering.

==See also==

* [[A-Scan Technique|A-scan technique]]
* [[B-Scan Technique|B-scan technique]]
* [[Imaging Ultrasonic Testing|Imaging ultrasonic testing]]
* [[C-Scan Technique|C-scan technique]]
* [[D-Scan Technique|D-scan technique]]
* [[F-Scan Technique|F-scan technique]]

'''References'''

* Oberthür, W.: Basiswissen Elektrotechnik/Elektronik für nicht elektronische Berufe. Books on Demand GmbH, Norderstedt (2010) (ISBN 978-3-8391-9273-3)
* Deutsch, V.; Platte, M.; Vogt, M.: Ultraschallprüfung – Grundlagen und industrielle Anwendungen. Springer, Berlin Heidelberg (1997) (ISBN 3-540-62072-9

'''Weblink'''

* Wikipedia – The free encyclopedia: Radio frequency: https://en.wikipedia.org/wiki/Radio_frequency

[[Category:Acoustic Test Methods_Ultrasonics]]

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