NVGate Output Signals

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This module generates multiple signals such as fixed sinus, random noises, and swept sinus.

Connect
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On the tab acquisition, output part is about the generated signal on the front-end outputs (generators)

The left button (signals) allows selecting the signal type from the list and connecting it to the available outputs (1 to 6) .The others buttons open the signal settings and manage the generators activity.

  • Reports_Tools_Ribbons_345.png Signals: Shows the list of available signals and let the users connect it to the outputs. You can easily connect signal with a "drag and drop" on the windows below.

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Sine: Opens the pure sine properties dialog for adjustment. Pure sine = 1 fixed frequency, 1 amplitude. Adapted for single mode excitation. Possibility to generate a fixed voltage with F=0.

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Multi-sine: Opens the Multi-sine properties dialog for adjustment. Multi sine = n fixed frequencies, 1 amplitude Adapted for multi-mode excitation and FFT analysis

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Swept-sine: Opens the Swept-sine properties dialog for adjustment. Swept-sine = 1 sweeping frequency, 1 to 6 proportional amplitudes Adapted for swept sine and MiMo excitation

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Chirp: Opens the Chirp properties dialog for adjustment. Chirp = Continuous short term variable frequency (1 analysis block), 1 amplitude. Adapted for damping measurement and FFT analysis

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Random Noise: Opens the Random noise properties dialog for adjustment. True Random noise = Infinity of frequencies, 1 amplitude, generated randomly. Adapted for non linear responses measurement. In addition to these predefined signals, the content of a file and the replication of an input is also available to be connected on the generators. See Chapter 1 ASB - § Resources/Output signals for details

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Outputs settings: Manages the generated signal settling, (Mute, transition time) See Chapter 1 ASB - § Front-end/Output settings for details

Sine

Used to generate and configure up to 6 fixed sinus. A sinusoidal signal is generated with the frequency specified in the sine Frequency field. The frequency corresponds to one of the analysis bands. This type of signal is used for measuring the amount of distortion in a system, for example. The amplitude of the signal can be changed using the Level settings.

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Frequency: sine frequency can be 0 for DC generation.

  • Peak level: the peak level
  • RMS level: sine RMS level. This setting can be displayed in dB.

Note: Amplitude and frequency modifications are applied immediately without any transition.

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Multi-sine

Multisine is computed by adding sine signals whose frequencies are power of two sub-modules of sampling frequency. This means that multisine output block includes all discrete sine waves of FFT spectrum of corresponding block size and resolution. Multisine has the advantage of showing no leakage effect in FFT as all sine waves are exact periods of the trigger block for FFT computation. The most appropriate FFT weighting window to be used is “uniform” window. Multisine generators work on a sample block basis, it means signal blocks are repeated identically over time.

Used to generate and configure up to 2 multi-sines. The multi-sine is computed by adding sine signals whose frequencies are power of two sub-modules of sampling frequency. So with the FFT analyzer, each sine signal can be exactly at an analysis frequency line and there is no leakage due to analysis window. Due to its specific structure, using a rectangular analysis window for FFT analysis on a multi-sine excitation is recommended.

The phase between sine signals can be controlled in order to get a low crest factor or randomized, but with a higher crest factor.


Multi-sine is periodic with a period equal to the opposite of its frequency resolution.

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  • Lower frequency: the lower frequency of the multi-sine frequency range. Its minimum value is the resolution.
  • Upper frequency: the upper frequency of the multi-sine frequency range. Its maximum value is SF / 2.56, where SF is the sampling frequency.
  • RMS level: multi-sine RMS level. This setting can be displayed in dB.
  • Resolution: the resolution of the multi-sine. Its minimum value is SF / 16384, where SF is the sampling frequency. Its maximum value is SF / 256.
  • Phase: Computational mode of the original sinusoid phases.
Phase Description
Random
The original phase of each sinusoid is selected randomly after each multi sine deactivation/activation.

First activation:

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After reactivation:

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Phase relationship between sine waves is selected at selection of setting and will not change unless “random” setting is changed back and forward. After “random” is selected phase relationship is defined (randomly for the first block) and repeated identically for each signal block of N lines. Phase relationship for all multisine generators will be different as random setting activation is made at different moment in time and applied for different generator objects. Two blocks of multisine random phase of the same generator are 100% correlated. Two mulitsine random phase generators are not correlated.

Fixed
Each sinusoid has the same original phase even after multi sine deactivation/activation.
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Multisine phase relation if fixed and will be the same each time setting “fixed” is selected. Phase relationship is the same for all multisine generators meaning that signal blocks will be the identical between any multisine generators of the same setting. Multisine fixed phase generators are 100% correlated.



Burst setting in Multisine generators will shorten time during which output signal is active despite signal block being of the same length. All bandwidth frequencies are present in each burst but may not be complete cycles as block period is truncated. Two bursts being identical (respectively fixed or random phase) they are 100% correlated. Two burst random from two separate generators will not be correlated signals.

Random noise

Used to generate and configure up to 2 white or pink random noise types.

Signal block is recalculated each time. All frequencies of generator bandwidth are taken into account with a resolution of Fs/16384 (Fs being front end sampling frequency), this resolution is independent from FFT resolution. Consequently signal content of each FFT trigger block is not the same meaning that signals between two trigger blocks are not correlated. Similarly random noise signal between two separate generators are also not correlated.

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Random noise is generated using algorithms that guarantee no short or long-term periodicity.

  • Lower frequency: the lower frequency of the Random noise frequency range. Its minimum value is equal to SF / (2.56 * 6400), where SF is the sampling frequency and 6400 + 1 is the resolution.
  • Upper frequency: the upper frequency of the Random noise frequency range. Its maximum value is SF / 2.56, where SF is the sampling frequency.
  • RMS level: the Random noise RMS level. This setting can be displayed in dB.
  • Period: The period selected for the Random noise. It used to define a Random Block. Its maximum value is 100ms.
  • Burst: This setting lets the user specify the percentage of non-null signal in a random block.
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  • Type:
Type Description
White White noise has the same distribution of power for all frequencies, so there is the same amount of power between 0 and 500 Hz, 500 and 1,000 Hz or 20,000 and 20,500 Hz.
Pink Pink noise has the same distribution of power for each octave, so the power between 0.5 Hz and 1 Hz is the same as between 5,000 Hz and 10,000 Hz. Since power is proportional to amplitude squared, the energy per Hz will decline at higher frequencies at the rate of -10dB/decade.


Chirp

Used to generate and configure up to 6 chirps. A sine signal, of which the frequency varies from Lower Frequency to Upper Frequency, is generated in the delay corresponding to the size of a generator block.

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  • Lower frequency: the lower frequency of the Random noise frequency range. Its minimum value is equal to SF / (2.56 * 6400), where SF is the sampling frequency and 6400 + 1 is the resolution.
  • Upper frequency: the upper frequency of the chirp frequency range. Its maximum value is SF / 2.56, where SF is the sampling frequency.
  • RMS level: the chirp RMS level. This setting can be displayed in dB.
  • Size: This setting specifies the number of samples required for the generator to go from the lower frequency to the upper one.
Block size FFT lines number
256 101
512 201
1024 401
2048 801
4096 1601
8192 3201
16384 6401


  • Burst: This setting lets the user specify the percentage of non-null signal greater than the size of a generator block. For instance, for a burst value of 25% and a block size of 1024, the generator delivers blocks of 256 samples of chirp separated by blocks of 768 null samples.
Size = 256

Burst = 70

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Advanced sine

Used to generate and configure up to 6 advanced sines, allowing the user to generate a swept sine, a pure tone, or to sweep step-by-step.

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  • Gain: Each advanced sine has a gain setting with a 0dB reference that is the value of the Advanced sine settings/ Peak level setting
  • Phase offset: All the advanced sine have the same phase reference. This setting is used to set a phase offset between them.
Advanced sine settings

This sub-module contains the settings related to the main advanced sine generator, including the advanced sine mode setting, stabilization time, amplitude variation...

  • Mode:
Mode Description
Sweep:

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The advanced sine performs a continuous sweep of the frequencies between Start Frequency and Stop Frequency











Step:
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The advanced sine performs a sweep of the frequencies between Start Frequency and Stop Frequency, it stops at each step, waits during stabilization time, and waits for the new step event before going on.
Pure tone:

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The advanced sine generates a pure sine with the frequency of the Advanced sine settings/ Target Frequency value


  • Synchronization: "linked to run" or "Free run". The Advanced sine generator will not be stopped by a stop event, if the setting is on ’Free run’. The default value is ’Linked to run’.

If you change the amplitude or the frequency of the generated signal, there will be a stabilization time, and you will have to generate an event when the signal is stabilized.

In those 3 modes, each time the generator stops on a frequency;

1. at the beginning (amplitude increase until the first frequency),

2. at a new step (at the end of stabilization time), or in ’pure tone’ or ’swept sine’ pause mode when it reaches the target frequency; the generator send a stabilized event, after being stabilized (amplitude and frequency).

3. In ’Free run’, if the generator is already stabilized at the run event, then a stabilized event is generated at this moment.

If the output is on ’Advanced sine’ source, the setting of ’Synchronization’ of the advanced sine will recopied to the ’synchronization’ of the output (which one become fixed).

Hidden/fixed:
Mode Sweep Step Pure tone
Synchronization Fixed to ’Linked to run’ Visible Visible


  • Pause: On / Off. When Pause is active, the frequency sweeping is halted then there is only one frequency generated. This frequency is now called "Target frequency". You can modify this frequency value to another target to be reached so the frequency will sweep to this new target.
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Hidden/fixed:

Mode Sweep Step Pure tone
Pause visible hidden hidden


  • Peak level: the advanced sine peak level (between 0 and 10 V).
  • Start frequency: The start frequency of the sweep.

Hidden/fixed:

Mode Sweep Step Pure tone
Start frequency visible visible hidden


  • Stop frequency: The stop frequency of the sweep.

Hidden/fixed:

Mode Sweep Step Pure tone
Stop frequency visible visible hidden


  • Target frequency: The value of this setting is the frequency currently generated when the value of the Pause setting is "On" or if the Mode is set to "Pure Tone"

Hidden/fixed:

Mode Sweep Step Pure tone
Target frequency visible if Pause = On visible if Pause = On visible


  • Sweep variation: Two different types of sweep are available: a linear sweeping or a logarithmic sweep:
Sweep variation Description
Lin The Sweep speed is constant
Log The Sweep speed increases exponentially when the frequency increase is linear


Hidden/fixed:

Mode Sweep Step Pure tone
Sweep variation visible fixed to Lin hidden


  • Sweep speed: It is expressed in Hz/s in a linear sweep variation, and in dec/s in a logarithmic sweep variation.

Hidden/fixed:

Mode Sweep Step Pure tone
Sweep speed visible hidden hidden


  • Sweep type:
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Sweep type Description
One shot The advanced sine sweeps the frequencies from Start Frequency to Stop Frequency and stops.
One cycle The advanced sine sweeps the frequencies from Start Frequency to Stop Frequency, then back to Start Frequency and stops.
Continuous The advanced sine sweeps the frequencies between Start Frequency to Stop Frequency without stopping.


Hidden/fixed:

Mode Sweep Step Pure tone
Sweep type visible visible hidden


  • Stabilization time: Sweep mode: Selects wait time for the advanced sine at the start frequency and at the right level before starting the sweep. Step mode: Selects wait time for the advanced sine at each step before waiting for the new step event.
  • Amplitude 'variation': Maximum length of time for the advanced sine to reach a new level.
  • Phase speed: Speed of phase variation when setting a new value for Advanced sine x/ Phase offset setting
  • Step: Frequency gap between two steps

Hidden/fixed:

Mode Sweep Step Pure tone
Sweep type visible visible hidden


  • New step: The event that triggers the sweep of the advanced sine to the next step

Hidden/fixed:

Mode Sweep Step Pure tone
Sweep type hidden visible hidden


Synchro

This special output signal is used to synchronize raw data recorded on multiple OR3X units (even OR2X). This synch signal must be connected on ext. synch trigger input of each recording unit (see below)

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  • Active: On/Off Set the synch signal available in sources list, no signal is generated on outputs at this stage
  • Generator Mode: Controls synch signal behavior.
  • On: start the synch clock generation (0 / +2 V square @ 50 Hz)
  • Off: stop the synch clock generation followed by a -2V step during 1 sec.

Track assembly procedure.

1. Activate the synch signal

2. Select Front-end / Output 1 / source = Synchro

3. Set Front-end / ext synch / coupling = DC on each recording unit

4. Set Front-end / ext synch / threshold = 1 V on each recording unit

5. Set Recorder/trigger/start = ext synch on each recording unit

6. Add ext. sync track to the recorder on each unit

7. Set same recording duration on each unit

8. Run each unit

9. Set generator mode = on to start record

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10. Download all recorded files on one PC

11. Launch ’Track Assembler’

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The concatenation synopsis is shown on the following scheme:

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More information on the Track Assembler in ’Operation on multiples Hardware’.

Input: listen during measurement

Back to the roots of vibration analysis: Everybody knows that our ears and brain is the best instrument to feel and interpret vibration signals. This is also why we take so much care in removing these NVH signals from our machines, vehicles and appliances. The audio playback of vibration (or any other) signal allows the user to "listen in" on what your OROS analyzer is "hearing".

Connect input feature allow a to play input channels on an output, then you can listen it during measurement with an headphone on the output.

Monitor channels : Hot Swap for listening channel on output

NVgate uses the monitor hot swap capability to allow changing the replicated signal during acquisition/recording.

The NVGate synopsis is as follows:

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To activate it, simply connect one of the monitor Channels to the desired output from the Acquisition/Outputs/Signal dialog.

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Then you can add any front-end input to the monitor channel. The selected input signal will replicate (play) on the output. You can swap form one input to another at any time including during the run and signal recording

NB: Remember to switch the output impedance to 600 Ω for better listening quality.

Player : play any signal on output

You can play a signal already record with OROS analyzer, or any signal imported in NVgate. Then this signal can be play on the ouptut.

Exemple : playing a triangle signal on analyzer output

• Generate a triangular signal with an application (Matlab,…) or an online site (example: http://onlinetonegenerator.com/);

• Save this signal in .wav;

• In NVGate, import this signal (File / Import / Files / OR2X Signal (* .wav, .mat, .UFF...);

• Load this signal in the player (right click then "load in player");

• In the options proposed in output, select the channel coming from the player:

•If you want to play this signal repeatedly, you must change the "Repeat mode" parameter in "Analyzer Setting Browser":

Play-Back on PC speaker

If you need to listen a signal already record, we advice to use the playback on PC speaker define here: From any of the previous configurations, the recorded signal could be listened on the PC loud speakers.

Click on   in the active window. The button stops the play back at any time. A mobile cursor (blue) localizes the played back signal part in the signal window.