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Guide to
Ultrasonic test system - LOPKUD-012
Software Revision 1.0 / 2002 |
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Hardware |
LOPKUD-012 is particularly
well suited for measurements with high power, low frequency
(<100kHz) ultrasonic waves. It can be used for testing
materials with high attenuation (scattering), such as stones,
concrete, wood etc. It can also be used for measurements
with air ultrasound (contact less transmission measurements).
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| Technical
data: |
| A/D
converter: |
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Resolution: |
8bits |
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- Sampling frequency: |
2MHz |
| Analog
parameters: |
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Input channels: |
1
BNC |
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Output channel: |
1
BNC |
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Input amplifier gain: |
0dB,
6dB, 14dB, 20dB, 26dB, 34dB, 40dB |
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Attenuator: |
-20dB |
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Input preamplifier gain: |
20dB,
30dB, 40dB, 50dB, 60dB, 70dB, 80dB |
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pre attenuator: |
-20dB |
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Input voltage: |
AC,
max. 20mVpp |
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Input impedance: |
700Ohm |
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Output voltage: |
max:
1000V |
| Data
buffer: |
4K |
| Triggering: |
external
(TTL Signal) |
| Signals
on the external connectors: |
DB9
Uin - measured input signal;
Ntrig - pulse generator control;
Kreg (out) - software controlled preamplifier gain
BNC
Uin - measured input signal
Ext_trg - external trigger
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Software: |
In order to use
LOPKUD-system, following equipment is necessary:
Computer System: IBM PC
Display Adapter: SVGA Adapter working in mode 640x480 or
higher (recommended 800x600)
Operations System: Windows 95, Windows 98, ME, XP and
Windows NT or 2000.
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Overview of Hotkey Selection: |
[F1] - Open - Load in a previously saved data file and
restore the capture settings as they were when the data was
saved
[F2] - Save as - This
option creates one file that contains both the current
settings and the current data. The setting saved are the
same in the Save Settings option.
[F3] Print This option will
create a hardcopy of the screen into IBM Graphics mode
compatible printers. The printout will include everything
currently on the screen.
[F4] About us… Short
information about OPTEL
[F5] Select port From the
settings window it is possible to change a board address,
and rs232 port.
[F6] Help a general help
screen is available that shows most hotkeys of the program
[F7] RUN / STOP enables /
disables selected acquisition mode
F8] Zoom / Spectrum choose
between Zoom and Spectrum display in bottom window (Zoom -
zoom for timing display; Spectrum - A set of functions which
perform transformations between the time domain and the
frequency domain, and perform analysis in the frequency
domain. These functions are based on the discrete
implementation of the Fourier Transform. Several rely on
frequency domain transformations to obtain the results
indirectly).
[F9] RF Signal / Detector
Choose between RF Signal and Detector display in upper and
bottom window.
[F10] Exit Exit to system
[F11] Show diagram Show
diagram of Ureg=f(N)
[F12] Transition [on/off]....
close and open of RS232 transmission from sender.
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On the scope screen: |
Memory three memories for
the measured signals
Grid ON/OFF toggle on/off the display of the division grid
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Measuring - Cells: |
Markers from Signal screen
and Zoom / Spectrum screen.
Time of flight [us]: It is necessary to prepare the signal,
that will be compared (correlated) with the actually
measured signal. If the transducer sends a short signal, it
is no problem with choosing a proper signal, but it is also
possible to choose any other signal. After the chosen signal
is visible on the Singal screen, and the markers positioned
on the left and right limit of the chosen signal, it is
necessary to switch the "Pattern". After it, the
bottom screen shows the chosen signal with the comment:
"Correlation Pattern". This step can be repeated
until the chosen signal is perfect. In the second step the
measurement should be started ("Measure").
Ureg[V].: sender signal amplitude
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Description of software for measurement of time of flight. |
This software package
allows to measure time of flight.
For each measurement it is
necessary to choose reference signal and compare it with the
signal, coming from the measured medium (reflected or
transmitted through it). This allows to use this software
with almost any kind of samples, containments etc. For
people using this software it is necessary to have some
knowledge about such kind of measurements, physics of
ultrasounds etc
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I. Introduction to the work with the software |
First step
Reference signal should be prepared, the best way to do it
is to use pure (distilled) water. Using markers in the upper
window most important part of the signal should be chosen.
In the bottom window signal between markers from the upper
window can be seen - magnified. See picture 1.
Picture 1.
Second
step.
Button "Pattern"
should be used. After pressing this button, chosen signal
appears in bottom screen in white color together with
information: "Correlation pattern". It means this
signal from this moment will be "reference signal".
See picture 2.
Picture 2.
From this
moment key called "Measure" should be used - all
subsequent operations will use signal stored before (pattern)
as reference for comparison with actually measured signal.
See picture 3. For time of flight measurement the display
will show 0 - nothing changed.
Third step
In this moment we have to repeat operations described in the
first step. In upper window we choose - using markers the
most important part of signal we are getting from measured
medium. In the bottom window we can see only signal between
markers from the upper window. See picture 4. Pay attention
on marker position (it is changed now). It means now we have
another signal (with time offset for example).
Picture 3.
In this moment
we have all information which is necessary for calculation
of time of flight (and another functions too), and then the
button "Measure" should be used . On the bottom
window we can see two earlier prepared signals (white -
reference signal; red - measure signal) in this case we
receive result different from zero.
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II. The time of flight and sound velocity measurement method. |
In most cases we can assume,
that the signal will change after propagation - simple
geometrical comparison of signals won't work properly. This
is the reason, why we are using following algorithm for
comparison of two signals with different time of flight:
a) FFT with Hamming window is made.
b) In frequency domain, frequency with maximum amplitude is
chosen and using relatively sharp windowing only this
frequency and frequencies from its neighborhood are taken.
c) Inverse FFT is done.
d) Center point of achieved signal is taken as time mark,
telling us the moment of "coming" of this signal.
Time of flight can be measured from zero point (start of
pulse) or from the time of "coming" of another
signal, stored as pattern - as described above.
If the path length is known, it is possible to calculate the
sound velocity in the measured material, using comparison
with reference fluid - for example water.
If the experimental setup have a containment with measured
fluid, where only a part of the sound propagation path is in
the measured fluid, we can wrote following formula:
T=T1+T2
Where T1 is time of propagation outside of measured fluid
and T2 in this medium.
We can measure time of flight in the whole system (T) filled
with water (TW, that has velocity CW), or measured fluid TX
(velocity CX). If we know the path length (L) in measured
fluid, we can calculate the velocity of sound in this
medium:
T2w=L/CW
T1=TW-T2W
This (T1) can be obtained after measurement with water, and
this measurement must be done only from time to time, since
parameters of system doesn't change quickly.
CX (sound velocity in measured medium) = L/(TX-T1)
The user of the software must know the path length (L), and
choose appropriate signals (not only direct transmission
must be chosen, but also multiple reflections for example).
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LOPKUD 012.PDF
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