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1064nm Picosecond-Pulsed Seed Laser Diode Source, With High-Speed Driver Electronics

  • 1064nm Pulse DFB with SOA and Driver Board
  • 1064nm Pulse DFB with SOA and Driver Board Specifications
  • 1064nm Pulse DFB with SOA and Driver Board Electrical Connector
  • 1064nm Pulse DFB with SOA and Driver Board Dimensions
  • 1064nm Pulse DFB with SOA and Driver Board Connections

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sku / item#: RLS/QCED106G
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Key Features
  • 1064 nm DFB Laser Diode, Integrated SOA
  • 50 Picosecond Gain-Switched Pulse Generation
  • Fully Realized Electronic Driver Module
  • 50 mW Peak Power
  • Internal / External Clock Operation
  • Single Shot to 200 MHz Repetition Rate
  • Flexible Parameter Control Via USB Interface

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OPTICAL Specifications
  • Optical pulse width (typical): 50 picoseconds (user adjustable to 9 nanoseconds)
  • Peak output power (typical): 50 mW
  • Pulsed side-mode suppression ratio (typical): >30 dB
  • Pulsed spectral line width (typical, under 50 ps pulse width): < 1 nm
Electrical specifications
  • Electrical pulse width tuning range: 50 to 9000 picoseconds
  • Repetition rate tuning range (internal clock mode): 0.012 - 200 MHz
  • Input power (Voltage): 5.25 VDC
  • Input power (Current): 4 Amps
  • Pulsed Seeder for Fiber Lasers
  • Time Resolved Measurement
  • 100 mm x 120 mm x 10.2 mm
  • Weight: 0.15 kg

Product Overview:

1064nm, Picosecond Pulse DFB Laser and Driver

These gain-switched picosecond pulsed seed laser sources from QD Laser are integrated onto a pre-configured 14-pin butterfly module control electronics board.

The system will deliver 50 picosecond optical pulses with stable single longitudinal mode operation can be obtained. Pulsing can be achieved via external or internal trigger sources from single shot to 250 MHz high repetition rate.

All of the operation parameters, including pulse peak current and laser diode temperature can be controlled by PC software and accessed via USB interface.

Proper Handling and Operation of Diode Lasers

Diode lasers are highly susceptible to damage from ESD and from temperatures exceeding their specified safe operating range. The user is advised to use care and proper ESD safety practices when handling them to avoid damage to the laser. A properly rated low noise current source, a low thermal resistance mount and a temperature controller should be used for optimal device performance and reliability.

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