Since several years, perspectives and assets offered by photonic technologies compared with their traditional  RF counterparts (mass and volume reduction, transparency to RF frequency, RF isolation), make them  particularly attractive  for space applications [1] and, in particular, telecommunication satellites [2]. However,  the development of photonic payload concepts have concurrently risen and made the problem of the ability of  optoelectronic components to withstand space environment more and more pressing. Indeed, photonic  components used in such photonic payloads architectures come from terrestrial  networks applications in order  to benefit from research and development in this field.  This paper presents some results obtained in the frame of an ESA-funded project, carried out by Thales Alenia  Space France, as prime contractor, and Alter Technology Group Spain (ATG) and Universidad Politecnica de  Madrid (UPM), as subcontractors, one objective of which was to assess commercial high frequency optical  intensity modulators for space use through a functional and environmental test campaign. Their potential  applications in microwave photonic sub-systems of telecom satellite payloads are identified and related  requirements are presented. Optical modulator technologies are reviewed and compared through, but not limited  to, a specific figure of merit, taking into account two key features of these components : optical insertion loss  and RF half-wave voltage. Some conclusions on these different technologies are given, on the basis of the test  results, and their suitability for the targeted applications and environment is highlighted

Barbero, Juan

Benazet, M.

Esquivias Moscardo, Ignacio

Karafolas, Nikos

Le Kernec, Arnaud

López Hernández, Francisco

Maignan, M.

Peñate, L.

Sotom, M.

English

Servicio de Coordinación de Bibliotecas de la Universidad Politécnica de Madrid

ICSO 2010                                                                     Rhodes, Greece 
International Conference on Space Optics                                                                             4 - 8 October 2010 
 
SPACE EVALUATION OF OPTICAL MODULATORS FOR MICROWAVE 
PHOTONIC ON-BOARD APPLICATIONS 
 
A. Le Kernec1, M. Sotom1, B. Bénazet1, J. Barbero2, L. Peñate2, M. Maignan1, I. Esquivias3, F. Lopez3, N. 
Karafolas4 
 
1Thales Alenia Space France, 26 Av. J.-F. Champollion – BP 1187, 31037 Toulouse Cedex1, France, 
E-mail : arnaud.le-kernec@thalesaleniaspace.com 
2
 Alter Technology Group Spain, Majada 3, 28760 Tres Cantos (Spain) 
E-mail : juan.barbero@alter-spain.com 
3
 Universidad Politecnica de Madrid, Escuela Tecnica Superior de Ingenieros de Telecommunicacion, Avenida 
Complutense s/n, Ciudad Universitaria, 28040 Madrid (Spain) 
E-mail : dxtn@tfo.upm.es 
4
 European Space Agency, ESTEC Keplerlaan 1 – PO Box 299 –2200 AG Noordwijk ZH – The Netherlands 
E-mail : Nikos.Karafolas@esa.int
 
 
I. INTRODUCTION 
 
Since several years, perspectives and assets offered by photonic technologies compared with their traditional 
RF counterparts (mass and volume reduction, transparency to RF frequency, RF isolation), make them 
particularly attractive  for space applications [1] and, in particular, telecommunication satellites [2]. However, 
the development of photonic payload concepts have concurrently risen and made the problem of the ability of 
optoelectronic components to withstand space environment more and more pressing. Indeed, photonic 
components used in such photonic payloads architectures come from terrestrial  networks applications in order 
to benefit from research and development in this field. 
This paper presents some results obtained in the frame of an ESA-funded project, carried out by Thales Alenia 
Space France, as prime contractor, and Alter Technology Group Spain (ATG) and Universidad Politecnica de 
Madrid (UPM), as subcontractors, one objective of which was to assess commercial high frequency optical 
intensity modulators for space use through a functional and environmental test campaign. Their potential 
applications in microwave photonic sub-systems of telecom satellite payloads are identified and related 
requirements are presented. Optical modulator technologies are reviewed and compared through, but not limited 
to, a specific figure of merit, taking into account two key features of these components : optical insertion loss 
and RF half-wave voltage. Some conclusions on these different technologies are given, on the basis of the test 
results, and their suitability for the targeted applications and environment is highlighted. 
 
II. OPTICAL MODULATORS APPLICATIONS IN TELECOMMUNICATION SATELLITES AND 
REQUIREMENTS  
 
Over the last two decades, optical modulators have been the object of intensive research and development 
activities in order to overcome the limited modulation bandwidth of laser diodes, and to meet the increasing 
bandwidth needs in terrestrial networks. Thanks to the effort to achieve higher modulation bandwidth (40 Gbit/s 
can currently  be achieved using electro-optic modulators), lower driving voltage and smaller size as well, these 
components become suitable for space systems and, associated with other optical components, are expected to 
bring significant improvements in signal handling in satellite payloads [3]. 
Among the possible applications of optical modulators in photonic payloads can be highlighted the generation 
and distribution of high frequency local oscillators, unachievable by direct modulation of the injection current of 
laser diodes, and the photonic RF frequency-conversion achieved by driving the modulator with the microwave 
signal to be down- or up-converted and feeding the optical input with an optical local oscillator. The major 
requirements for these modulators and for the applications mentioned above are presented in Table 1. 
 
III. OPTICAL MODULATOR TECHNOLOGIES 
 
During past decades, several kinds of optical intensity modulators have been developed and marketed based 
on the following technologies [4] : Lithium Niobate (LN) electro-optical modulators, polymeric electro-optical 
modulators, semiconductor electro-optical modulators and semiconductor electro-absorption modulators. 
 
 
 
ICSO 2010                                                                     Rhodes, Greece 
International Conference on Space Optics                                                                             4 - 8 October 2010 
Table 1. Major specifications for optical modulators 
ITEM TARGET FIGURE 
Operating wavelength 1520-1600 nm 
Max. input optical power handling 200 mW 
Optical insertion loss ≤ 3 dB 
RF operating frequency up to 40 GHz 
RF driving voltage (or power)  @ 
30GHz ≤ 4 V  (≤ +16 dBm) 
Linearity : carrier-to-3rd 
intermodulation > 60 dBc 
Impedance 50 ohms 
RF return loss (in the band) > 15 dB 
Optical fibre input / output PMF  / PMF or SMF  
Package hermetic 
Volume < 8 cm3 
Mass < 20 g 
Lifetime > 15 years 
 
Electro-optical modulators are based on the so-called Pockels effect, i.e the change of the refractive index of 
the material by applying an electrical field. Depending on the material used and the crystal orientation, the 
modulators can exhibit quite different characteristics. 
Lithium Niobate (LN) electro-optical modulators : two configurations of modulators using Lithium Niobate 
are commercially available, which determine the locations of electrodes with respect to optical waveguides : the 
X-cut and Z-cut modulators. Both have respective assets and drawbacks : Z-cut have lower RF half-wave 
voltage than X-cut but their stability due to thermally induced effect is questionable. 
Semiconductor (SC) electro-optical modulators : these modulators, which are based on III-V semiconductors 
of the GaAs or InP family possess a linear-electro-optic effect. The intensity modulation is based either on the 
classical integrated Mach-Zehnder interferometer or on polarization modulation. An important advantage of 
these modulators is their high potential of integration. 
Polymeric electro-optical modulators : Mach-Zehnder modulator can also be realised using polymer materials. 
These modulators are based on molecules called chromophores, presenting strong dipole moments and strong 
hyperpolarisability, incorporated in the polymer host. These modulators offer high electro-optical coefficient 
and very high modulation bandwidth. Nevertheless, they suffer from significant optical losses and their 
chemical stability under high power and high temperature is still to be proven. 
 
The electro-absorption modulator (EAM) is based on the Franz-Keldysh effect (or the quantum confined 
Stark effect in a quantum well structure), which consists in changing the absorption spectrum of a 
semiconductor (InP) by applying an electric field. The main assets of these modulators are their lowest driving 
voltage and the smallest size with respect to other modulator types. However, the maximum optical power 
handling is low and they are wavelength dependent. 
 
IV. MODULATORS SELECTION AND TESTS 
 
In order to assess the suitability and the critical design issues of commercial optical intensity modulators for 
applications in photonic sub-systems of future satellite payloads, performances of modulators, based on the 
different technologies previously described, have been first compared using informations gathered from 
datasheets and using features, such as the optical power handling capability and the following figure of merit 
(FoM):  
 
2
1010










=
−
driveV
α
FoM  (1) 
where α is the optical insertion loss, and Vdrive is the driving voltage for 100% modulation at the operating 
frequency (i.e Vπ, the effective half-wave voltage in case of a Mach-Zehnder modulator), which was fixed at 30 
GHz given the considered applications. This figure of merit expresses the amount of modulated optical power 
ICSO 2010                                                                     Rhodes, Greece 
International Conference on Space Optics                                                                             4 - 8 October 2010 
that can be made available at the output of a modulator, for a certain amount of RF drive power. Therefore, the 
higher the FoM, the higher the gain and the better. 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
Fig. 1. a. Measured FoM of selected modulators. b. Static response of a Z-cut LN modulator during gamma 
radiation test. 
This first selection stage discarded electro-absorption modulators because of their too low optical power 
handling capability for the targeted applications. A set of 14 modulators representing the remaining technologies 
from different suppliers has been procured and submitted to functional and environmental tests. Functional tests 
aimed at assessing several features such as optical insertion loss, DC half-wave voltage, extinction ratio, RF 
half-wave voltage at 10, 20 and 30 GHz. Some results of these functional tests is given in Fig. 1.a. through the 
measured FoM. Further tests aimed at assessing the evolution of these parameters when  selected modulators are 
submitted to environmental stresses including maximum and minimum temperature (0°C and 70°C), mechanical 
shocks, vibrations, thermal vacuum cycling and radiations (gamma and protons), as shown in Fig. 1.b. In Fig. 
2.a. and b. are respectively presented the bandwidth evolution during the environmental test campaign and the 
Figures of Merit before and after the whole test campaign of modulators having exhibited the best behaviors 
during all these tests. 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
Fig. 2. a. Normalized bandwidth variations of several modulators during the environment tests. b. Measured 
FoM of best modulators, before and after the whole test campaign. 
 
 
0
5
10
15
0 2 4 6 8 10
Optical Insertion Loss (dB)
D
riv
e
 
Vo
lta
ge
 
@
 
30
 
G
H
z 
(V
)
FoM=0,1
FoM=0,2
FoM=0,4
FoM=0,8
FoM=1,6
X-cut - Sample 1 - Initial
X-cut - Sample 1 - Final
X-cut - Sample 2 - Initial
X-cut - Sample 2 - Final
X-cut - Sample 3 - Initial
X-cut - Sample 3 - Final
Z-cut - Initial
Z-cut - Final
Semiconductor - Initial
Semiconductor - Final
 
0,0
0,2
0,4
0,6
0,8
1,0
1,2
1,4
Me
ch
an
ica
l
Th
er
m
al 
Va
cu
um
Ra
dia
tio
ns
N
o
rm
a
liz
e
d 
RF
 
ba
n
dw
id
th
X-cut - Sample 1
X-cut - Sample 2
X-cut - Sample 3
Z-cut
Semiconductor - Sample 1
Semiconductor - Sample 2
0
5
10
15
0 1 2 3 4 5 6 7 8 9 10
Optical ins ertion los s  (dB)
D
riv
e
 
vo
lta
ge
 
@
 
30
G
H
z 
(V
)   
 
X-cut, LN EOM
Z-cut, LN EOM
SC EO M
  FoM = 0.1
  FoM = 0.2
  FoM = 0.4
  FoM = 0.8
  FoM = 1.6
-35
-30
-25
-20
-15
-10
-5
0
5
-20 -16 -12 -8 -4 0 4 8 12 16 20
DC Bias (V)
R
e
la
tiv
e
 
O
pt
ic
a
l O
u
tp
u
t Initial
10 krad
30 krad
60 krad
100 krad
Annealing 24h
Annealing 168h
Annealing 70° 168h
a. b. 
a. b. 
ICSO 2010                                                                     Rhodes, Greece 
International Conference on Space Optics                                                                             4 - 8 October 2010 
V. TEST RESULTS 
 
The evaluation campaign including both functional and environmental test items was conducted on a number 
of samples selected so as to be representative of various technologies and procured from different suppliers [5].   
Some conclusions from the functional test campaign are :  
- X-cut Lithium Niobate modulators exhibit overall performance slightly worse than expected (compared 
to predictions from datasheets) ; 
- Z-cut Lithium Niobate modulators exhibit overall performance slightly better than expected ; 
- There was a substantial difference between functional performance of  X-cut and Z-cut LN modulators; 
- Polymer modulator sample was found immature (the test campaign was interrupted because of the 
component failure) ; 
- Low drive voltages can be obtained with Semiconductor modulator and Z-cut LN modulators ; 
 
Some conclusions from the environmental test campaign are given hereafter : 
- Modulators based on different technologies exhibited very different behaviours (stable/not stable, 
degraded/not degraded) all along the environmental test campaign; 
- Most of the tested modulator samples have the capability to operate at least in the [0-70°C] temperature 
range; 
- The insertion losses of both semiconductor and lithium niobate modulators were not affected by 
temperature variations; 
- In most cases, Lithium Niobate and semiconductor electro-optic modulators exhibited a slight decrease 
of the DC half-wave voltage with increasing temperature. 
- Only a few modulator samples were found unstable in temperature, as the static response shifted during 
measurements (even some X-cut lithium niobate modulators); 
- The RF bandwidths were not much affected by changes in the temperature range considered (variations 
lower than +/- 20 %); 
- Some of the tested modulator have proven their capability to withstand the mechanical test conditions. 
Both optical and electrical continuity were well preserved; 
- A few modulator samples were damaged during mechanical shock tests. The RF input was broken or 
damaged, and failure was revealed by S11 measurement; 
- A number of modulators withstood all undergone environmental tests and did not exhibit any 
catastrophic damage; 
 
VI. CONCLUSIONS 
 
Optical intensity modulators have been identified as key components to perform functions such as generation 
and distribution of optical local oscillators or optical mixing in future telecommunication payloads. Several 
technologies are commercially available exhibiting different levels of performance and maturity for space 
applications. In order to assess these technologies, some modulators from different suppliers and covering these 
different technologies have been procured and submitted to a full test campaign encompassing functional as 
well as environmental tests. 
Among them, lithium niobate and semiconductor electro-optical modulators turn out able to withstand most of 
environmental tests while keeping good overall performances and so appear as the best technologies for space 
applications at 1.55 µm.  
 
REFERENCES 
 
[1] N. Karafolas, J. M. Perdigues Armengol, I. McKenzie, “Introducing Photonics in Spacecraft Engineering : 
ESA’s Strategic Approach”, IEEE Aerospace Conference, Big Sky, Montana, March 7-14, 2009. 
[2] J. M. Perdigues Armengol, N. Karafolas, I. McKenzie, “ESA Developments on Optical Technologies in 
Support of Advanced Photonic Flexible Telecom Payloads”, ESA Workshop on Advanced Flexible 
Telecom Payloads, Noordwijk, The Netherlands, 2008. 
[3] M. Sotom, B. Bénazet, M. Maignan, “A Flexible Telecom Satellite Repeater Based on Microwave 
Photonic Technologies”, Proc. 6th Internat. Conf. On Space Optics, ESTEC, Noordwijk, The Netherlands, 
2006. 
[4] G. L. Li and P.K.L. Yu, “Optical Intensity Modulators for Digital and Analog Applications,” Journ. Of 
Light. Tech., vol. 21, no. 9, pp. 2010-2030, September 2003. 
[5]  M. Sotom, B. Bénazet, A. Le Kernec, L. Penate, J. Barbero, E. Cordero, F. Lopez, M. Maignan, 
“Assessment of Commercial High Frequency Optical Intensity Modulators for Space Applications”, 
International Symposium on Reliability of Optoelectronics for Space, Cagliari, Italy, May 11-15, 2009. 


Space Evaluation of Optical Modulators for Microwave Photonic On-Board Applications

Archivo Digital UPM

A Flexible Telecom Satellite Repeater Based on Microwave Photonic Technologies”,

Introducing Photonics in Spacecraft Engineering : ESA’s Strategic Approach”,

Optical Intensity Modulators for Digital and Analog Applications,”

Space Evaluation of Optical Modulators for Microwave Photonic On-Board Applications

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