Go Back
By Industry
By Technology
Synopsys Cloud
Synopsys Cloud

Cloud native EDA tools & pre-optimized hardware platforms

Request a Free Trial →
Multi-Die System Solution
Multi-Die System Solution

A comprehensive solution for fast heterogeneous integration

Discover Multi-Die →
View All Solutions →
Explore Silicon Design, Verification & Manufacturing

Synopsys is a leading provider of electronic design automation solutions and services.

Families
Optical Design
Photonic Design
Design
3D Image Processing
Verification
Modeling & Simulation
Manufacturing
Try Synopsys Cloud
Synopsys Cloud

Unlimited access to EDA software licenses on-demand

Request a Free Trial →
Explore Silicon IP

Synopsys is a leading provider of high-quality, silicon-proven semiconductor IP solutions for SoC designs.

Interface IP
Processor IP
Analog IP
Memories & Libraries
SoC Architecture
Security IP
SoC Infrastructure IP
IP Accelerated
IP Markets
Synopsys IP Portfolio Cover
Synopsys IP Portfolio
Download Brochure →
Synopsys IP Technical Bulletin
Read Latest Issue →
Explore Application Security

Synopsys helps you protect your bottom line by building trust in your software—at the speed your business demands.

Integrated AppSec Solutions
Software Risk Analysis
AppSec Program Services
Your guide to securing your open source supply chain
Your guide to securing your open source supply chain
Read the report →
View All Products →
Company Overview
Resources
SNUG 2024 | Synopsys
SNUG 2024

Synopsys User Group Conference

Learn more →
Synopsys Job Search Thumbnail
Pursue Your Passion

Start Your Job Search

Apply Now →

EDFA Gain Modulation

Tool Used: OptSim

This example demonstrates modulation of a pump’s optical power to produce gain modulation in an EDFA, and is based on the parameters and results in [1]. The simulation uses Transient simulation mode in OptSim.

A 980 nm pump and 1530 nm signal are launched into a 10.5 m EDFA, modeled via the Compact Transient EDFA model. The input signal power is fixed, while the pump power is modulated as

Compact Transient EDFA model | Synopsys
where Ppo is the average pump power, mp is the modulation index, f_mod is the modulation frequency, and t is time.

Figure 2 shows the modulated 980 nm pump and constant 1530 nm signal inputs to the EDFA (analogous to Figure 4 from [1]), plotted using Tplotter1, while Figure 3 shows the corresponding EDFA outputs (analogous to Figure 5 from [1]), plotted using TPlotter2. As can be seen, the average powers gradually approach steady state, with the pump still showing modulation, and the signal also showing very slight modulation as well due to the modulated EDFA gain.

Note that the above approach for modulating the pump power can be extended to other expressions, including random power variations. 

Schematic demonstrating EDFA dynamic response to a modulated pump input | Synopsys

Figure 1. Schematic demonstrating EDFA dynamic response to a modulated pump input.

EDFA input signals, showing modulated pump at 980 nm | Synopsys

Figure 2. EDFA input signals, showing modulated pump at 980 nm.

EDFA outputs, showing evolution towards steady state | Synopsys

Figure 3. EDFA outputs, showing evolution towards steady state, modulated output pump, and slight modulation of output signal.

Reference

1.       S. Novak and R. Gieske, “Simulink model for EDFA gain dynamics applied to gain modulation,” Journal of Lightwave Technology, vol. 20, no. 6, pp. 986-992, June 2002.