Characterization of the Bias Current Behavior in a SOA for

Linearizing Amplification in a CO-OFDM System

Julio C. Ortiz-Cornejo

and Jorge A. Pardiñas-Mir

2 a

Technological University of Jalisco, Guadalajara, Mexico

Department of Electronics, Systems and Informatics, ITESO University, Tlaquepaque, Mexico

Keywords: CO-OFDM, Semiconductor Optical Amplifier, Bias Current, Linearization, Error Vector Magnitude.

Abstract: This paper presents an analysis of the semiconductor optical amplifier (SOA) on coherent optical orthogonal

frequency division multiplexing system (CO-OFDM), when it is used as a booster power amplifier. The

semiconductor optical amplifier is driven by their bias current injection, which control the amplification level.

In this sense, this study analyses the impact of bias current change on a SOA based CO-OFDM system. It is

well known that SOA is prone to nonlinear distortion when high input power is used at high gain level, because

the gain saturation. In addition to the aforementioned analysis, here it is also presented three operation

scenarios to characterize the performance of the system: maximum EVM equal to 20%, constant output power

equal to -7 dBm, and constant SOA Gain equal to 17 dB. This let us obtain a way to optimize the SOA

performance, under each scenario, controlling the bias current.

1 INTRODUCTION

Amplification process is a crucial step in the coherent

optical orthogonal frequency division multiplexing

(CO-OFDM) systems. Given the inherent nature of

the CO-OFDM signal to generate high peaks of

signal, it condition could drive the optical amplifier to

gain saturation, and signal distortion at the receiver

(Rahmatallah, 2013). Because of it, the optical

amplifiers are one of the key components in the CO-

OFDM systems (Khaleghi, 2013). Recently the

semiconductor optical amplifiers (SOA) has been

extensible studied as a good candidate in CO-OFDM

systems, due to the cost-effective characteristics

(Azou, 2015), (Renaudier, 2019). However, SOA still

have some points to solve, for instance, SOA can

exhibit nonlinear behavior when it operates in

saturation region. These nonlinearities can cause

problems such as frequency chirping and generation

of inter-modulation products (Bendimerad, 2017).

One way to avoid these undesirable effects is to

regulate dynamically the bias current (I

bias

) to control

de SOA amplification, in order to avoid SOA gain

saturation.

The principal application of SOA can be divided

in three main functions: power booster of transmitter,

https://orcid.org/0000-0002-0972-3980

in line amplifiers, and optical preamplifier. The

booster amplifiers are placed at the optical transmitter

side to enhance the transmitted power level or to

compensate for the losses of optical elements between

the laser and optical fibers, such as optical couplers,

and external optical modulators. In-line amplifiers are

placed along the transmission link to compensate the

losses incurred during propagation of optical signal.

Optical preamplifiers are used to increase the signal

level before photo-detection occurs, improving the

receiver sensitivity (Shieh, 2010).

This study aims to analyze the impact of bias

current change in the SOA behaivor, used as a booster

for a back-to-back CO-OFDM transmission. To

achieve this goal, we use a simulation system based

on Matlab for digital signal processing of modulation-

demodulation, and ADS for the SOA model

simulation. This simulator has been used before in

(Khaleghi, 2013), (Younes, 2017) showing good

consistence between simulation and experimental

results.

The rest of this report is organized as follows.

Section II presents the simulation results given by the

bias current change on SOA based CO-OFDM system

for a wide range of input power (P

) levels. In Section

III we go into the analysis of bias current functions to

Ortiz-Cornejo, J. and Pardiñas-Mir, J.

Characterization of the Bias Current Behavior in a SOA for Linearizing Ampliﬁcation in a CO-OFDM System.

DOI: 10.5220/0007931502430248

In Proceedings of the 16th International Joint Conference on e-Business and Telecommunications (ICETE 2019), pages 243-248

ISBN: 978-989-758-378-0

243

control the EVM, output power (P

out

) or optical gain

(Gain), also we analyzed the benefits and

disadvantages of these three approaches. Section IV

gives the conclusions of this study.

2 BIAS CURRENT CHANGE IN

SOA

As mentioned before, we simulate a back to back CO-

OFDM transmission, using the SOA as a booster

amplifier, as seen in Figure 1. The system was

simulated with 128 subcarriers, 4 QAM baseband

modulation, electrical bandwidth of 5 GHz, and an

oversampling factor os = 4.

Figure 1: A SOA as a booster amplifier in a CO-OFDM

transmitter.

The objective of the simulation is to characterize

the impact of the SOA bias current I

bias

on three main

aspects of its behaviour as amplifier within a CO-

OFDM system: gain (G), output power (P

out

), and

error vector magnitude, (EVM). All this under

different conditions of the input power P

. To achieve

this goal, we measured the aforementioned variables

for a range of different input powers, from -31 dBm

to -6 dBm, in steps of 1 dBm. For each test point, we

variates the bias current from 65 mA to 315 mA in

intervals of 1 mA. This gives a total of 6526 tests.

These values have been chosen in order to include the

linear and nonlinear SOA operation.

2.1 EVM Function of P

and I

bias

First, we run simulations to obtain the behavior of the

EVM for variations of the bias current and the input

power. Figure 1 shows graphically the results. Here

we can observe that the way EVM changes when the

input power and the bias current increase. The EVM

rises rapidly for high values of I

bias

and P

. For

example, the system can get up to 40 % EVM for a

equal to -16 dBm for values of I

bias

of 345 mA.

Figure 2: EVM function of P

and I

bias

in CO-OFDM

system with SOA as booster amplifier.

2.2 P

out

Function of P

and I

bias

The simulations for obtaining the behaivor of the

output power, related to variations of the bias current

and the input power, produced the results shown in

Figure 2. As already known (Saleh, 1988), the output

power level of the amplifier, for a specific input

power value, can be controlled by selecting the right

bias current. As a reference, for an input power of -16

the amplifier can produced around 5 dBm at its output

for a EVM of 40% when using a I

bias

of 345 mA. Both

figures allow us to have a broad view of the behavior

of the amplifier for different conditions.

Figure 3: SOA output power function of P

and I

bias

2.3 Gain Function of P

and I

bias

Figure 3 illustrates the behaviour of the amplifier’s

gain. We can clearly see the direct dependence of the

gain of the amplifier with respect to the current. Here,

the maximum gain is obtained for low input powers.

For example, the amplifier’s gain is 22 dB for an input

power of -28 dBm. On the contrary, there is a

reduction of the gain for high input powers.

Figure 5 shows the gain curves versus bias current

and input power with more detail. It is clearer

OPTICS 2019 - 10th International Conference on Optical Communication Systems

244

Figure 4: SOA Gain function of P

and I

bias

observed the gain reduction as the input power

increases for a constant bias current.

Figure 5: Detail of SOA Gain function of P

and I

bias

2.4 Bias Current for Minimum EVM

We are interested in characterizing the behaivor of the

SOA under certain conditions. One condition is to

obtain the minimum possible EVM regardless of the

value of the input power. We want to know what

current to use to achieve this.

We can get a model from each result of the EVM

obtained in subsection 2.1 for each input power value.

As an example, Figure 6 shows the curves of the

EVM function the bias current for two different input

powers: -22 dBm and -17 dBm. Using a MATLAB

fitting function we obtain the polynomials described

in equations (1), for -22 dBm,, and (2), for -17 dBm.

Figure 6: EVM function of P

and I

bias

for two different

input powers.

The next step to obtain a model for all input

powers, is to search the minimum EVM of each

single-variable polynomial function by using a

constrained variable I

bias

as follows:

mAImAIEVM

biasbias

bias

31565)(minarg 

(3)

We applied linear regression to obtain the model

described by equation (4). This equation shows what

is the bias current needed to obtain the minimum

EVM for a given input power. The curve of such a

function is illustrated in Figure 7.

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We run a test in the simulator of the CO-OFDM

system using the previous function. We introduced a

signal with different input powers, for each power we

used a different bias current, calculated with the

equation (4) and we computed the EVM of the

received signal. Figure 8 shows the results (variable

bias) comparing it with those obtained with a fixed

current. In this case value of the current is 150 mA.

The observation of parallel results of the

simulations let us find that the cost of minimizing the

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Characterization of the Bias Current Behavior in a SOA for Linearizing Ampliﬁcation in a CO-OFDM System

245

Figure 7: Bias current function of P

and I

bias

to obtain the

minimum EVM.

Figure 8: EVM function of P

applying bias current

corresponding to each power level to obtain minimum

error.

error is forcing a decrease in output power, originated

by decreasing the gain. This is expected, since the

decrease in current decreases the gain of the

amplifier. Both behaviors are shown in Figure 9 and

Figure 10. This model allows us to know exactly how

the amplifier behaves controlling the current to

achieve the smallest EVM depending the input

power.

The search of minimal EVM by controlling I

bias

drives the SOA to a Gain depletion and Pout

attenuation. In such a case, a good profile of bias to

get a sufficient gain with a certain acceptable level of

distortion at the receiver (EVM) is needed.

Figure 9: Output power response when bias current change

for minimum EVM and Pout curve when bias current is

constant 150 mA, It drives CO-OFDM system to a

amplification fail above Pin = -18 dBm.

Figure 10: EVM function of P

out

applying bias current

corresponding to each power level to obtain minimum

error.

3 IMPACT OF BIAS CURRENT

ON SOA PERFORMANCE

From the previous results, it is clear that it is

necessary to find a good trade-off between EVM and

out

to have a good operational level in amplification

terms. Therefore, we propose three different profile

behaivors to analyse the impact of the bias current on

the SOA.

The first profile is obtained under the condition of

keeping the EVM at a maximum of 20%. The second

profile consists in preserving a constant P

out

equal to

-7 dBm. The third scenario to investigate is for a

constant SOA Gain of 17 dB over the whole P

range

analysed previously. We search in the results

obtained in the previous section: EVM, P

out

and Gain

function of I

bias

and P

, for the values of I

bias

, for each

value of P

, that fits the conditions of each of the

OPTICS 2019 - 10th International Conference on Optical Communication Systems

246

aforementioned profiles. From these values, we

estimate a linear regression to get I

bias

functions

depending of P

, to control de SOA amplification

according to one of the three desired profiles. This

can allow, for example, automating the envelope-

tracking scheme proposed in (Ortiz, 2017).

3.1 Maximum EVM Equal to 20%

According to the results shown in Figure 2 for EVM

function of I

bias

and P

, we observe that EVM is

relatively low, EVM < 20 %, for the linear region P

< -19 dBm, so we define an I

bias

equal to 200 mA to

obtain a SOA Gain of 20 dB with low EVM. On the

other hand, for high input power, P

> -19 dBm,

which is the SOA nonlinear region, we define an

EVM threshold of 20%, gradually decreasing I

bias

keep the EVM equal to 20% for -19 < P

< -6. The

results are shown in Figure 11. Here, we observe that

Pout decreases as a consequence of I

bias

reduction.

Also we can observe the SOA Gain attenuation in

accordance with the I

bias

decrease. Moreover, SOA

Gain has a linear decrease, and I

bias

has a nonlinear

decrease.

Figure 11: EVM and bias current for a maximum EVM of

20% at different input powers.

We compute from the Ibias current points a linear

regression to get an Ibias model. Since the complexity

of the Ibias behavior, we use a rational model, which

is a polynomial over a polynomial:

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3.2 P

out

Equal to -7 dBm

We search into the results for P

out

, function of I

bias

and P

, the bias current values to get P

out

equal to -7

dBm all along the P

range (from -31 dBm to -6

dBm). The results are shown in Figure 12.

Figure 12: EVM and bias current for a constant P

out

equal

to -7 dBm.

We can see that EVM has values below 15%, even

in high P

values. It shows a quasi-linear response. In

addition, SOA gain has a linear decrement, this effect

reduces SOA gain saturation and, therefore, EVM is

low. This condition could be a drawback in the case

where we need to have a high gain for a P

above -19

dBm.

The I

bias

behavior is modeled by a 4th degree

polynomial as shown as follows:

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3.3 Constant SOA Gain of 17 dB

In this scenario, we search in the results for Gain,

function of Ibias and Pin, obtained in subsection 2.3,

the Ibias values needed to keep a SOA gain equal to

15 dB. These values are shown in Figure 10.

This profile shows a clear inconvenient when the

is higher than -20 dBm: the EVM increases

exponentially. This is due to the distortion caused by

the amplifier at such ouptut region. We can observe

also that the SOA gain has an inverse behavior

compared to P

out

in the second profile.

Characterization of the Bias Current Behavior in a SOA for Linearizing Ampliﬁcation in a CO-OFDM System

247

Figure 13: EVM and bias current for a constant SOA gain

of 15 dB.

These results can be modelled by a 6th degree

polynomial function:

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4 CONCLUSIONS

The characterization of a SOA used as a booster

amplifier in a CO-OFDM system has been presented.

We investigated the way the bias current and the input

power affects the SOA performance in terms of EVM,

output power, and Gain. We demonstrated that a

trade-off to obtain a good behaivor is needed,

depending three different scenarios of operating

conditions. We analysed the performance profile and

developed a formula to compute the bias current

values that fits to each of three scenarios: maximum

EVM equal to 20%, constant output power equal to -

7 dBm, and constant SOA Gain equal to 17 dB. These

formulas would allow to dynamically controlling the

bias current to obtain the best results within each

operating scenario.

ACKNOWLEDGEMENTS

This work was supported in part by CONACYT

(Consejo Nacional de Ciencia y Tecnología, Mexican

Government) through a scholarship granted to J. C.

Ortiz-Cornejo.

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