Post on 29-Jan-2016
Implementing a 10 Gb/s VCSEL Driven Transmitter for Short Range Applications
Irfan N. AliMichael C. Clowers
David S. FinkSean K. Garrison
Jeff A. Magee
Georgia Institute of TechnologySchool of Electrical & Computer Engineering
March 3, 2008
Project Objectives & Parameters
Objective: Design and implement 10 Gb/s VCSEL transmitter for fiber optic Ethernet systems
Client: Telecom service providers, server management groups, etc.
Projected Unit Cost: Approx. $700
• Design and implement a 10 Gb/s optical link• Digital/electrical input• Signal processing via laser driver• Electrical-Optical Signal conversion via VCSEL• Analog/optical output • Fiber optic data transmission• Bit-error-ratio tester (BERT)
Technical Objectives
Laser Driver
VCSELFiber Optic Cable
Pattern Generat
orBERT
Driver Board Interface Board
Technical Specifications
Bit Rate 10 Gb/s Nominal Wavelength 850 nm Power Supply 3.3 V Output Fiber 50-um Multimode Output Connector LC Board Dimensions Variable Max Transmission Range 100 m
Design Approach
• Three parallel approaches:• Modify MAXIM Inc. evaluation board• Populate existing Analog Devices (AD)
driver board• Design driver board for TI chip
Laser Driver
VCSELDigitalInput
IMOD
IBIAS
Analog Devices Board
• Pre-designed board• Needs to be populated and tested• Has analog control of output currents
Laser Driver
Digital Inputs
Output to VCSEL
Maxim Inc. Evaluation Board
• Evaluation board designed for laser diode
• Interface board designed to deliver limited modulation and bias currents to VCSEL
Digital Inputs
Laser Driver
Tuning Potentiometers
Output to Interface Board
TI Driver Board Schematic
• Driver board designed using PCB Artist• Provides digital control of output currents• Works with an interface board to connect to VCSEL
MCU InputDigital InputsPower Supply
Digital Outputs
VCSEL Interface Board Schematic
• Interfaces the TI and MAXIM Inc. boards with the VCSEL
• Includes resistance networks to limit current to VCSEL
Digital Input
Digital Inputs
Analog VCSEL Output
Analog VCSEL Output
MAXIM Interfa
ce
TI Interfa
ce
System Configuration
Note: SMA connections use coax cables Optical cables use LC connectors
Demonstration Plan
• Test by using the transmitter with a pattern generator to a send 10 Gb/s signal to error detector connected to optical receiver
• Measure bit-error-ratio (BER) versus optical power at receiver and compare to acceptable value of BER at 10-10
• Capture optical eye diagram using a high-speed oscilloscope
Problems/Issues
• Transmission lines for interface board need to be designed for high speeds
• SMA pad size on AD board does not match the SMA connector specification
• VCSEL connection to AD board may be incompatible with available VCSELs
• TI driver chip has 0.5 mm spacing between pins which will be difficult to solder by hand
Budget & Cost Analysis
Unit Cost Analysis
Fringe Benefits (% of labor) 25%
Overhead (% total labor, parts, fringe) 50%
Marketing (% sales price) 25% Warranty (% sales price) 5%
Costs (per unit) Materials $220
Labor $20
Testing $20
Fringe Benefits (25% labor cost) $5 Overhead $133
Sales/Marketing $250
Warranty $50
Amortized Development Costs $2.28
Cost Subtotal $700
Devices Acquired MAXIM Inc. Eval Board $300 Circuit Components Free Driver Chips Free Predesigned PCB Free Total Costs $300 Non-Budget Spending TI MCUs $80 Future Spending Circuit Components TBA SMA Connectors TBA
Power Supplies TBA
PCB Boards $80
•TI MCUs were bought as general use for the Senior Design Lab and therefore will not come out of the budget•Pre-designed PCB board
provided free of charge from Dr. Ralph’s lab
•Costs are based on total unit sale of 15000 over 5 years
Projected Schedule
Major Events Before Spring Break:•Completing PCB design and fabrication•Populating pre-designed board•Testing at TSRB
Current Status
• MAXIM Inc. evaluation board acquired• AD board partially populated• TI and interface boards designed • PCB mounting design initialized
Questions/Comments
Thank You