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ACTA IMEKO 
December 2013, Volume 2, Number 2, 61 – 66 
www.imeko.org 

 

ACTA IMEKO | www.imeko.org December 2013 | Volume 2 | Number 2 | 61 

Digital demodulator unit of laser vibrometer standard for in 
situ measurement 
Akihiro Oota1, Hideaki Nozato1, Wataru Kokuyama1, Yoshinori Kobayashi2, Osamu Takano2, Naoki 
Kasai2 

1 National Institute of Advanced Industrial Science and Technology, Central 3, 1-1-1 Umezono, Tsukuba, Japan 
2 Neoark Corporation, 2062-21 Nakanomachi, Hachioji, Tokyo, Japan 

 

 

Section: RESEARCH PAPER  

Keywords: Laser vibrometer; analog demodulator; digital demodulator; ISO 16063-41 

Citation: Akihiro Oota, Hideaki Nozato, Wataru Kokuyama, Yoshinori Kobayashi, Osamu Takano, Naoki Kasai, Digital demodulator unit of laser vibrometer 
standard for in situ measurement, Acta IMEKO, vol. 2, no. 2, article 11, December 2013, identifier: IMEKO-ACTA-02 (2013)-02-11 

Editor: Paolo Carbone, University of Perugia 

Received February 18th, 2013; In final form September 23th, 2013; Published December 2013 

Copyright: © 2013 IMEKO. This is an open-access article distributed under the terms of the Creative Commons Attribution 3.0 License, which permits 
unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited 

Funding: This work was financially supported by METI (Ministry of Economy, Trade and Industry), Japan 

Corresponding author: Akihiro Oota, e-mail: a-oota@aist.go.jp 

 

 

1. INTRODUCTION 
Laser vibrometers have been frequently used for precise 

vibration measurements to ensure the safety of commercial 
products in industry. The reliability and accuracy of such 
measurements should be guaranteed by a traceability system, 
which is a series of calibrations meeting national or 
international metrology standards regarding the use of laser 
vibrometers. To establish such a traceability system for laser 
vibrometers, a novel calibration method has been published as a 
new international standard (ISO 16063-41 [1]) for laser 
vibrometers. Some demonstrations have been attempted in 
accordance with this standard [2-5]. 

Laser vibrometers consist of two key components, a laser 
optics unit and a demodulator unit. A heterodyne laser 
interferometer or homodyne laser interferometer can be applied 
with a laser optics unit. The interferometry signal detected by a 
laser optics unit is transformed into an acceleration, velocity, or 
displacement signal by the demodulator unit. Two kinds of 
demodulator unit, analog and digital types, can be applied to 
realize this transformation. 

For many years, many analog demodulator units have been 
used to transform interferometry signals into velocity signals. 
These units enable the direct conversion from Doppler signals 
to velocity signals, which can be continuously obtained over a 
wide velocity or frequency range. Such a laser vibrometer based 
on Doppler signals is referred to as a laser Doppler vibrometer. 
In an analog demodulator unit, the characteristics of the electric 
components such as the frequency-to-voltage converter, low-
pass filter, and scaling amplifier strongly affect the 
measurement accuracy [6]. 

On the other hand, the digital demodulator unit applies a 
new signal processing method that does not depend on the 
characteristics of analog components. Because of the wide 
bandwidth of the interferometry signals, the only analog device 
required is an analog-to-digital converter (ADC) with high 
speed and high resolution. In the digital demodulator unit, the 
measurement accuracy depends mainly on the characteristics of 
the ADC and the calculation algorithm. 

Therefore, the digital demodulator unit would enable users 
to easily achieve high measurement accuracy, in contrast with 
that obtained with the analog demodulator unit. However, 

ABSTRACT 
To establish an easy-to-use traceability system for laser vibrometers in vibration acceleration standard, a highly accurate reference 
standard is required. In this study, we investigated the measurement reliability of a commercial laser vibrometer with an analog 
demodulator. The results confirmed a large measurement deviation from nominal sensitivity values due to characteristics of the 
analog demodulator. To reduce such deviation, a high-accuracy digital demodulator, which can be utilized as a reference standard, 
was developed. The experimental results confirmed the improved measurement accuracy of the developed digital demodulator.



 

ACTA IMEKO | www.imeko.org December 2013 | Volume 2 | Number 2 | 62 

digital demodulator units cannot always provide continuous 
measurements over the wide velocity or frequency range 
achieved by analog demodulator units because of technical 
barriers such as the limited number of samples available for 
digital processing and the limited sampling rate [6]. 

In this study, characteristics of various types of commercial 
laser vibrometer were investigated, and we clarify the 
disadvantages of the analog demodulator unit used. In addition, 
a novel digital demodulator unit, which enables us to 
continuously provide output data for in situ measurement, was 
developed to realize high measurement reliability, and we 
confirmed its capability experimentally. 

2. CHARACTERISTICS OF COMMERCIAL LASER VIBROMETER 
WITH ANALOG DEMODULATOR UNIT 

2.1. Characteristics of three commercial laser vibrometers 

To confirm the potential of commercial laser vibrometers, 
we performed the calibration of a laser vibrometer and its 
demodulator unit. Three different kinds of commercial laser 
vibrometers with analog demodulators were applied to the 
calibration, which are in this work denominated LV A, LV B 
and LV C. These laser vibrometers are made by three 
manufacturers in Japan.  

The primary calibration of the laser vibrometer using 
practical vibrations was performed in accordance with ISO 
16063-41 (fringe counting method and sine approximation 
method). Figure 1 shows the experimental setup used for the 
primary calibration of the laser vibrometer. The laser 
interferometry system used as a reference standard is the 
homodyne laser interferometry system included in the Japanese 
national standard for primary calibration of accelerometers. In 
this setup, the fringe counting method was applied for the 

frequency range 20 Hz – 80 Hz, and the sine approximation 
method was applied for the frequency range 100 Hz – 5 kHz. 

In addition, their demodulator units are electrically calibrated 
with simulated frequency modulated signals, which are 
equivalent to output signals obtained from the laser optics unit 
in the calibration in accordance with ISO 16063-41. Figure 2 
shows the experimental setup used for the demodulator unit 
calibration. A radio frequency (RF) signal generator was applied 
to generate the simulated frequency-modulated signal. An r.m.s. 
voltmeter (or digitizer) measures the output voltage of the 
demodulator unit. The RF signal generator and r.m.s. voltmeter 
can be calibrated through a traceability system of the time 
standard and voltage standard, respectively. 

Figure 3 shows primary calibration results of the laser 
vibrometers LV-A, LV-B and LV-C, and also the electrical 
calibration results of their respective demodulator units. These 
demodulators were set for a nominal sensitivity of 
10 (mm/s)/V. The calibration results of the demodulator units 
show very similar characteristics to the laser vibrometer 
calibration results.  

Figure 4 shows the corrected primary calibration results 
based on the demodulator unit calibration results. Although the 
results from two different calibration methods had a large 
deviation of more than 1.0 % from nominal sensitivities as 
shown in Figure 3, a small deviation of less than 0.5 % was 

 
Figure 1. Experimental setup of primary calibration of a laser vibrometer.

RF signal generator Analogue demodulator r.m.s. voltmeter

RF IN OUT

RF signal generator Analogue demodulator r.m.s. voltmeter

RF IN OUT

 

Figure 2. Experimental setup of demodulator unit calibration. 



 

ACTA IMEKO | www.imeko.org December 2013 | Volume 2 | Number 2 | 63 

almost achieved by performing a correction based on their 
demodulator unit calibration results. 

The small deviation after correction in Figure 4 may 
normally be due to the effect of the optics unit of the laser 
vibrometer. However, all results after correction would be 
expected to be similar to each other. Therefore, the deviation 
after correction would be due more to the systematic error 
from common components in the demodulator unit calibration, 
such as the simulated frequency-modulated signal from the 
radio frequency signal generator, and not so much by the effect 
of the optics unit as by the systematic error from the common 
component in the demodulator unit calibration.  

2.2. Linearity and frequency dependency of the laser vibrometer 

The experiments mentioned above were carried out for a 
specific frequency series as accelerometer calibration. However, 
as the basic principle of a laser vibrometer, the frequency shift 
of light scattered from a moving surface by the Doppler-effect 
is proportional to the velocity of the moving surface. Therefore, 
the nonlinearity of the velocity amplitude may be more 
significant than the frequency characteristics. In this study, both 
typical characteristics were evaluated in detail for the LV-C. The 
setting of the nominal sensitivity value was fixed during the 
evaluation. Figure 5 shows the relative deviation from nominal 
sensitivity obtained while the velocity amplitude is adjusted 
from 3 mm/s to 100 mm/s at a calibration frequency of 160 
Hz. Nonlinearity higher than 5 % was observed in this case.  

Figure 6 shows the frequency characteristic of LV-C and its 
demodulator C at constant velocity amplitude of 10 mm/s. The 
relative deviation from nominal sensitivity changes 
approximately 0.7 % between 20 Hz and 5 kHz. 

As the sensitivity fluctuation due to the velocity amplitude is 
much larger than that due to the frequency, the linearity for the 
velocity amplitude may be as important for in situ 
measurements as the sensitivity of the laser vibrometer. The 
evaluation results of the demodulator unit are very similar to 
the evaluation results of the laser vibrometer. As a result, we 
can conclude that the drastic fluctuation of the laser vibrometer 
sensitivity would be mainly due to the analog demodulator unit. 

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Demodulator C LV C

Figure 3. Comparison between calibrations of commercial laser vibrometers 
(LV) and electrical calibration of its demodulator unit calibration. The LVs of
three different manufacturers were set at a nominal sensitivity of 10
(mm/s)/V. A, B and C: different manufacturers. LV: Laser vibrometer. 

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LV B after correction
LV C after correction

Figure 4. Correction results based on demodulator unit calibration. 

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Figure 5. Typical nonlinearity for velocity amplitude at 160 Hz for a nominal 
sensitivity of 10 (mm/s)/V. 

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Figure 6. Typical frequency characteristic for nominal sensitivity of 
10 (mm/s)/V (Velocity amplitude of sinusoidal vibration given by vibration 
exciter is fixed at 10 mm/s). 



 

ACTA IMEKO | www.imeko.org December 2013 | Volume 2 | Number 2 | 64 

Consequently, to ensure the measurement reliability of the 
laser vibrometer in measurement ranges not covered by the 
primary calibration of the laser vibrometer in accordance with 
ISO 16063-41, the appropriate electrical calibration for analog 
demodulator units would be very useful to extrapolate the 
sensitivity. However, if a more precise vibration measurement is 
required, the measurement accuracy of the demodulator unit 
should be improved. 

3. DEVELOPMENT OF THE DIGITAL DEMODULATOR UNIT 

3.1. Preliminary comparison between the digital demodulator 
unit and the analog demodulator unit 

In ISO 16063-41, the digital signal processing for the 
decoding of the Doppler signal is required in the definition of 
laser vibrometer standards. Therefore, to develop a higher 
accuracy demodulator unit, the potential of digital 
demodulation should be investigated by comparing it with 
analog demodulation. This comparison was carried out using 
electrical calibration and primary calibration explained above in 
Section 2. 

In this experiment, LV-C was used as the laser vibrometer 
with the analog demodulator unit. The optics part of LV-C can 
be detached from the analog demodulator unit because it was 
specially designed for this purpose. On the other hand, to 
conveniently achieve digital demodulation, a commercial signal 
analyzer (Anritsu MS2690A) was applied. By using this 
instrument, I & Q signals (in-phase and quadrature-phase signal 
pair) can be easily obtained, and the decoding of the I & Q 
signals is then performed by our proprietary software using 
LabVIEW. The signal analyzer has an ADC resolution of 16 
bits, a maximum sampling rate of 50 MHz, and an RF down-
conversion function. In this experiment, the signal analyzer and 
RF signal generator used to generate the simulated FM signal 
use a common sampling clock signal for their own processing. 

To implement a laser vibrometer with a digital demodulator 
unit, the optics part of LV-C was connected to the signal 
analyzer.  

Figure 7 shows the evaluation results obtained from both 
the primary calibration and electrical calibration. It compares 
the primary calibration results obtained for LV-C with the 
analog demodulator C, with the analog demodulator C after 

correction, with the digital demodulator, and the electrical 
calibration result of only the digital demodulator unit. As a 
result, the potential of the digital demodulator unit to achieve 
higher measurement accuracy is confirmed. 

3.2. Development of the digital demodulator unit for in situ 
measurements 

Based on the results shown in Section 3.1, the digital 
demodulator unit with higher accuracy for laser vibrometer is 
now discussed. Although the application of the signal analyzer 
led to good results in the preliminary experiment, the signal 
analyzer would be unsuitable as it cannot continuously output 
data in real time, as required for in situ measurements. 
Therefore, a dedicated digital demodulator unit, which has a 
smaller deviation than commercial analog demodulator units, 
and which generates continuous output in real time, was 
designed for in situ measurements.  

The developed digital demodulator unit is constructed with 
an ADC, digital to analog converter (DAC), and field-
programmable gate array (FPGA) at low cost. A He-Ne laser is 
used as the laser source in almost all commercial laser 
vibrometers in Japan. The driving frequency of its acousto optic 
modulator (Bragg cell) in the laser optics unit is fixed at 80 
MHz. The maximum frequency shift due to the Doppler effect, 
which is equivalent to the maximum measurable velocity, is set 
to 10 MHz to cover the velocity range below 3 m/s. Thus the 
maximum frequency of the signal to be detected by the ADC is 
equivalent to 90 MHz. To satisfy the Nyquist sampling theorem, 
a sampling rate of more than 200 MHz is required as the 
maximum sampling rate of the ADC at least. To implement the 
measurement with higher accuracy in this study, the ADC is 
selected to have two channel inputs, a high sampling rate of 500 
MS/s, and a high resolution of 12 bits. The DAC has a high 
sampling rate of 250 MS/s and a high resolution of 16 bits. 
High-speed signal processing is required to obtain the 
demodulation signal in as close to real time as possible. FPGA 
can process data faster than DSP. Therefore, an FPGA was 
applied to achieve high-speed signal processing for 
demodulation at low cost. The data processing including the 
digital demodulation algorithm embedded in the FPGA was 
developed to satisfy the requirement for the laser vibrometer 
standard described in ISO 16063-41. Additionally, ADC, DAC 
and FPGA are driven with common clock signal. 

The specifications of the ADC, DAC and FPGA are given 
to enable continuous measurements over a wide frequency 
range of up to several hundred kHz. This digital demodulator 
unit can receive a carrier frequency signal of either 80 MHz or 
10 MHz, which will enable it to immediately process the 
frequency signal after down conversion. In addition, the higher 
accuracy measurement can be achieved by applying a high-
accuracy 10 MHz external clock to this demodulator unit. 
Figure 8 shows a photograph of the developed digital 
demodulator unit. 

The developed digital demodulator unit was evaluated using 
the same experimental setup in the previous section under the 
same experimental conditions as the analog demodulator unit. 
Figure 9 and Figure 10 show typical evaluation results obtained.  

Experimental results showed that the relative deviation is 
confirmed to be below 0.3% for three frequency series in the 
applicable measurement range, and the time delay of the output 
due to the signal processing is evaluated to be about 30 μs. 
These results indicate that the developed digital demodulator 

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Digital demodulator unit
LV C with analog demodulator unit
LV C after correction
LV with digital demodulator unit

Figure 7. Preliminary comparison of digital demodulation with analog
demodulation. 



 

ACTA IMEKO | www.imeko.org December 2013 | Volume 2 | Number 2 | 65 

unit has a sufficiently high measurement accuracy to be 
applicable as part of a laser vibrometer standard. 

 

 

3.3. Practical shock measurement using a laser vibrometer with 
the developed digital demodulator unit 

The prototype of the developed digital demodulator unit 
must be combined with the laser optics unit to work as a laser 
vibrometer for in situ measurements. Therefore, the 
performance of the laser vibrometer, which consists of the 
developed digital demodulator unit and a commercial laser 
optics unit, was demonstrated using a shock acceleration exciter. 
To generate a rectilinear motion for sensing, a shock 
acceleration exciter was used for primary shock acceleration 
calibration as a national standard in Japan [7]. To validate the 
capability for sensing, in this experiment, a homodyne laser 
interferometer in a shock acceleration calibration system was 
used as the reference standard. 

Figure 11 shows typical experimental results. The peak 

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DD at 1000Hz
DD at 160Hz
DD at 5000Hz
AD at 1000Hz
AD at 160Hz
AD at 5000Hz

applicable measurement range

 
Figure 9. Typical evaluation results of the relative sensitivity deviation for 
the developed digital demodulator unit. DD: digital demodulator unit. AD: 
analog demodulator unit. 

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Figure 10. Typical evaluation results of the phase shift for the developed 
digital demodulator unit (phase shift). DD: digital demodulator unit. AD: 
analog demodulator unit. 

 

(a) Overview of the developed digital demodulator unit 

 

(b) Internal view of the developed digital demodulator unit 

Figure 8. Digital demodulator unit for the laser vibrometer developed in this 
study. 

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Figure 11. Comparison of typical measurement results of the laser 
vibrometer with prototype of the developed digital demodulator unit and 
shock acceleration standard with homodyne laser interferometer in NMIJ. 
DD: laser vibrometer with prototype of the developed digital demodulator 
unit. Ref.std.: homodyne laser interferometer for the shock acceleration 
standard in NMIJ. 



 

ACTA IMEKO | www.imeko.org December 2013 | Volume 2 | Number 2 | 66 

acceleration sensed by the reference standard was about 
1700 m/s2. From a comparison of both velocity waveforms, a 
slight time delay was observed in the laser vibrometer with the 
developed digital demodulator unit. This result is in agreement 
with the result of the phase shift obtained in Figure 10. In 
addition, the waveform that was obtained indicates unstable 
behavior after the application of shock acceleration. This 
instability may be due to the nonlinearity of the sensitivity to 
small velocity changes, and is a future technical issue to be 
investigated. 

4. CONCLUSIONS 
The characteristics of a laser vibrometer with an analog 

demodulator unit were investigated using three different 
commercial laser vibrometers. The calibration results of these 
demodulator units show very similar characteristics to those of 
the laser vibrometer calibration. Most of the deviation from the 
nominal sensitivity is due to the characteristics of the 
demodulator unit used. 

The measurement accuracy of the laser vibrometer with a 
digital demodulator unit was compared with that of a laser 
vibrometer with an analog demodulator unit using the same 
laser optics unit. The results confirmed the higher measurement 
accuracy of the digital demodulator unit. 

To overcome the difficulty of realizing a continuous signal 
processing for in situ measurement, the digital demodulator 
unit was developed using an FPGA, an ADC with a high 
sampling rate, and a DAC with a high sampling rate. The 
excellent potential of the developed digital demodulator unit 
was experimentally confirmed. On the other hand, we observed 
unstable behavior on the application of shock acceleration. This 
instability should be addressed to ensure greater usefulness for 
a laser vibrometer standard. 

ACKNOWLEDGEMENT 

This work was performed by AIST, and is a research project 
aimed at supporting small and medium companies. We 

acknowledge the financial support provided by the METI 
(Ministry of Economy, Trade and Industry). We deeply 
appreciate the kind cooperation of the two main Japanese 
manufacturers of laser vibrometers. We also wish to thank Dr. 
H-J.von Martens, who drafted ISO 16063-41, for the useful 
discussions. 

REFERENCES 

[1] ISO 16063-41: Methods for the calibration of vibration and 
shock transducers – Part 41: Calibration of laser vibrometers, 
International Organization for Standardization (2011). 

[2] H.-J. von Martens, T. Bruns, A. Taubüner, W. Wabinski, U. 
Göbel, Recent progress in accurate vibration measurements by 
laser techniques, 7th International Conference on Vibration 
Measurements by Laser Techniques: Advances and Applications, 
Ancona, Italy, 2006, Vol. 6345, pp. 634501-1-23. 

[3] A. Oota, T. Usuda, T. Ishigami, H. Nozato, H. Aoyama, and S. 
Sato, Preliminary implementation of primary calibration system 
for laser vibrometer, 7th International Conference on Vibration 
Measurements by Laser Techniques: Advances and Applications, 
Ancona, Italy, 2006, Vol. 6345, pp. 634503-1-8.  

[4] U. Buehn, and H. Nicklich, “Calibration of laser vibrometer 
standards according to the standardization project ISO 16063-
41”, 7th International Conference on Vibration Measurements by 
Laser Techniques: Advances and Applications, Ancona, Italy, 
2006, Vol. 6345, pp.63451F-1-9. 

[5] G. P. Ripper, G. A. Garcia, and R. S. Dias, The development of a 
new primary calibration system for laser vibrometer at 
INMETRO, IMEKO 20th TC-3, 3rd TC-16 and 1st TC-22 
International Conference, Mérida, Mexico, 2007, paper ID-105. 

[6] M. Bauer, F. Ritter, and G. Siegmund, High-precision laser 
vibrometers based on digital Doppler-signal processing, 5th 
International Conference on Vibration Measurements by Laser 
Techniques: Advances and Applications, 2002, Vol. 4827 
pp. 50-61. 

[7] H. Nozato, T. Usuda, A. Oota, T. Ishigami, Calibration of 
vibration pick-ups with laser interferometry Part IV: 
Development of shock acceleration exciter and calibration 
system, Measurement Science and Technology, Vol. 21, No. 6, 
(2010), paper ID 065107, pp. 1-10.