Ytterbium-Doped Fiber Amplifiers (YDFA), 1 µm

Saturation Output Power of >20 dBm
Broad 1025 - 1075 nm Operating Range
Optimized for Ultrafast Pulse Amplification
Simple, Turnkey Operation

YDFA100P

Polarization-Maintaining YDFA

YDFA100S

Single Mode YDFA

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Overview
Specs
Graphs
fs Pulse Amplification
Software
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This plot gives the output power as a function of input power for our polarization-maintaining YDFAs. A complete set of performance graphs is available on the Graphs tab.

Features

Operating Wavelength Range: 1025 - 1075 nm
>22 dB Small Signal Gain and 20 dBm Typical Output Power (See Graphs Tab for Values Over Wavelength Range)
Ideal for Use as a Preamplifier for Ultrafast and CW Applications
Single Mode or Polarization-Maintaining Versions Available
Front Panel Controls and Remote Control over USB

Thorlabs' Core-Pumped Ytterbium-Doped Fiber Amplifiers (YDFAs) offer 20 dBm (100 mW) typical output power with a low noise figure of <8 dB. Each is enclosed in a compact, turnkey benchtop package with FC/APC input and output connectors. In order to support applications involving femtosecond pulses, they are engineered to impart minimal dispersion. Each YDFA includes built-in input and output isolators to minimize back reflections to the amplifier and light source. Custom amplifiers with higher output power and gain is also available upon request; please contact techsupport@thorlabs.com with inquiries.

Versions for single mode or polarization-maintaining operation are available. The YDFA100S uses HI1060 single mode fiber with <0.3 dB polarization-dependent gain. The YDFA100P is a polarization-maintaining amplifier with input and output isolators that block light polarized along the fast axis of the PM980-XP fiber. Therefore, the YDFA100P is designed to work with input signals polarized along the slow axis of the fiber. Output light from the amplifier has a polarization extinction ratio of >20 dB. The input and output fiber connector keys are aligned to the slow axis of the fiber.

The pump current of the ytterbium-doped fiber amplifier is adjustable through the instrument's front panel, allowing the user to vary the gain and output power of the amplifier. In addition, remote control of the pump current is supported by sending serial commands via a USB 2.0 connector. For added safety, the user may connect an interlock circuit to the 2.5 mm mono jack on the rear panel.

Each YDFA uses a universal power supply allowing operation over 100 - 240 VAC, 50 - 60 Hz without the need to select the line voltage. A region-specific power cord is included.

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YDFA100P Front Panel
The front panel of the YDFAs include a digital display, a rotating knob that adjusts the pump laser current, a key switch, and an amplifier enable switch button paired with a green LED.

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YDFA100P Back Panel
The back panel of the YDFAs include a USB type B connector for remote operation and a 2.5 mm mono jack for a user-designed interlock circuit.

Unless otherwise indicated, all values are specified for a CW input beam at 1050 nm.

Item #	YDFA100S	YDFA100P
Amplifier Specifications
Operating Wavelength Range	1025 - 1075 nm
Output Power (@ 3 dBm Input Power)^a	19 dBm (Min) 20 dBm (Typical)
Small Signal Gain (@ -20 dBm Input Power)^a	>22 dB
Noise Figure^a	<8 dB
Output Power Stability (@ 3 dBm Input Power)	<±2% Over 24 Hours(After 15 Minute Warm-Up, for Ambient Temperature ±2 °C)
Total Absolute Dispersion within Amplifier	<0.2 ps/nm
Laser Class	3B
Fiber Specifications
Output Polarization	Random	Linear Aligned to Slow Axis
Polarization Extinction Ratio	N/A	>20 dB
Polarization-Dependent Gain	<0.3 dB	N/A
Return Loss at Input Port	>50 dB
Input / Output Isolation	>20 dB
Input / Output Fiber Type	HI1060	PM980-XP
Input / Output Fiber Connectors	FC/APC Compatible, 2.0 mm Narrow Key

Please refer to the Graphs tab for the variation of each parameter over a range of wavelengths and input powers.

Absolute Maximum Ratings
Absolute Maximum Input Power	10 dBm
Absolute Maximum Output Power	23 dBm
Operating Temperature	15 to 35 °C
Storage Temperature	0 to 50 °C

General Specifications
Input Voltage	100 - 240 VAC, 50 - 60 Hz
Input Power	20 VA (Max)
Fuse Rating	500 mA
Fuse Type	IEC60127-2/III (250 VA, Slow Blow Type "T")
Dimensions (W x H x D)	5.77" x 3.07" x 12.17" (146.5 mm x 77.9 mm x 309.1 mm)
Weight	1.96 kg (4.32 lbs)
Connections and Controls
Interface Control	Optical Encoder with Push Button
Enable Select	Keypad Switch Enable with LED Indicator
Power On	Key Switch
Fiber Connectors	FC/APC Compatible, 2.0 mm Narrow Key
Input Power Connector	IEC Connector
Interlock	2.5 mm Mono Jack
Communications
Communications Port	USB 2.0 Compatible
COM Connection	USB Type B Connector
Required Cable	USB Type A to Type B Cable (Replacement Item # USB-A-79)

Performance Graphs

Unless otherwise stated, all performance graphs below were obtained using a CW input, the maximum pump current of 1000 mA, and the factory pump temperature setting of 25 °C. Performance may vary from unit to unit; this data reflects the typical performance of our YDFAs, and is presented for reference only. The guaranteed specifications are shown in the Specs tab.

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Click for Raw Data
Typical Output Power as Function of Input Power

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Typical Output Power at 1050 nm as Function of
Pump Current

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The typical gain as a function of the wavelength. The blue-shaded region denotes the specified operating wavelength range.

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The typical noise figure as a function of the wavelength. The blue-shaded region denotes the specified operating wavelength range.

Simulation Model Parameters (Using the YDFA100P)
Input
Pulse Width	50 fs	100 fs	200 fs
Pulse Energy	26 pJ
Peak Power	>450 W	>240 W	>120 W
Output
Pulse Width	3.8 ps	3.3 ps	2.7 ps
Peak Power	>300 W	>350 W	>400 W
Output with Compression
Pulse Width	103 fs	120 fs	145 fs
Peak Power	>10 kW	>8 kW	>6 kW

Femtosecond Pulse Amplification

Ultrafast pulses amplified by a YDFA will experience some pulse broadening due to dispersion effects. This dispersion is a natural consequence of light moving through the doped gain fiber and other fiber components and cannot be eliminated completely. Thorlabs' YDFA amplifiers optimize the gain fiber length to minimize dispersion and nonlinearity while maximizing the amplification gain. After amplification, the pulse can be compressed to attain a pulse width closer to the input pulse. The fibers used in the YDFA100P and YDFA100S have identical dispersion and nonlinearity and thus can both be used in femtosecond applications.

Simulated results of amplification for three different input pulses through the YDFA100P amplifier are shown in the graphs below and the table to the right. The input pulses are specified at 1045 nm and 26 pJ pulse energy, and with a 50 fs, 100 fs, or 200 fs pulse width. The YDFA amplifier simulations set the gain at 1045 nm to 17.1 dB and use the measured gain spectral shape in calculating the amplified pulse. In addition, the YDFA is modeled with 1 m of polarization-maintaining fiber before and after the amplifier. Finally, the results below also show simulated pulse compression of the post-amplification pulse using a pair of 1200 lines/mm diffraction gratings. Optical loss in the grating pair has been neglected for the calculation of the peak power values shown in the table.

50 fs Pulse Width
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100 fs Pulse Width
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200 fs Pulse Width
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Experimental Validation of YDFA100P Amplification

This experiment combines measurement of an amplified pulse in the YDFA100P with numerical simulation of the expected output pulse. A 117 fs input pulse was generated using a 100 MHz oscillator. The YDFA100P was used to amplify the pulse from a 2.6 mW average power to 140 mW, and then the output pulses were compressed using an external pulse compressor. The input and output pulse intensity profiles were characterized using frequency-resolved optical gating (FROG) measurements.

The results shown below indicate that the amplified pulses were compressible to their original width due to the low nonlinearity and third-order dispersion effects in the YDFA. Simulations of the input and output pulse using the model discussed above are also shown alongside the experimental data and show relative agreement with the experimental results. The fibers used in the YDFA100P and YDFA100S have identical dispersion and nonlinearity and thus can both be used in femtosecond applications.

LBNL Test
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Experimental and numerically simulated pulses before amplification and after with pulse compression are shown. Experimental data is provided courtesy of Tong Zhou and Russel Wilcox at Lawrence Berkeley National Laboratory.

Amplifier Comparison

Fiber amplifiers such as EDFAs and YDFAs are typically better suited than semiconductor optical amplifiers (e.g., BOAs and SOAs) for amplifying femtosecond laser pulses. These amplifier types differ in their saturation energies, their gain saturation dynamics, and their free carrier lifetimes. In semiconductor amplifiers, the saturation energies are relatively low, on the order of a few picojoules. This limits the amplified pulse energy that can be achieved by semiconductor amplifiers. By way of comparison, in fiber amplifiers, the saturation energies exceed microjoule levels. Additionally, the gain recovery times in semiconductor amplifiers are governed by the carrier lifetime, which is in the 10 ps to 100 ps timescale. The carrier lifetime of fiber amplifiers is typically in the 10 µs to 1 ms timescale.

Consider the case of a mode-locked femtosecond laser with a repetition rate on the order of 1 MHz. For pulse energies well below the saturation energy of the semiconductor amplifiers, the pulses will be amplified with minimal distortion. However, once the pulse energy exceeds the saturation energy, the amplification will saturate during the pulse, leading to a gain difference over the pulse's temporal profile and distorting the pulse shape. Since fiber amplifiers have higher saturation energies than semiconductor amplifiers, they are less prone to experience gain saturation by this mechanism.

Because the gain recovery time of a semiconductor amplifier (10 ps to 100 ps timescale) is shorter than the repetition period, the gain medium recovers before the next pulse in the pulse train arrives at the semiconductor amplifier. Therefore the same process is repeated for each pulse. In fiber amplifiers, the free carrier lifetime (10 µs to 1 ms timescale) is much longer than the repetition period. Consequently, fiber amplifiers can be thought of as responding to the pulse's average power, as opposed to its peak power.

An additional point that is especially relevant to femtosecond pulses is the role of nonlinear processes in the amplifier. While the nonlinear response of a fiber amplifier is almost instantaneous, the nonlinear response time of a semiconductor amplifier is in the 10 ps to 100 ps timescale, as it is related to its carrier lifetime. This ps timescale represents another source of pulse distortions when the pulse energy exceeds the saturation energy.

YDFA Drivers

Version 2.12.18

Includes drivers required to control our YDFA100S and YDFA100P fiber amplifiers in a Windows^® environment.

The YDFA100S and YDFA100P contain the following components:

Ytterbium-Doped Fiber Amplifier in Benchtop Package
Amplifier Enable Key (Qty. 2)
Interlock-Shorting Pin
Region-Specific Power Cord
FBC250 Connector and Bulkhead Cleaner
Manual

Posted Comments:

user (posted 2019-12-09 00:20:38.833)

May I know whether YDFA100P work with signal at low repetition rates and ns pulse widths (eg., pulse width 3-5 ns; repetition rate: 10-100kHz. What is the minimum repetition rate on can operate for ns pulse amplification? What is the maximum input peak power for the amplifier at which gain of 22dB is available?

YLohia (posted 2019-12-12 03:51:57.0)

Hello, thank you for contacting Thorlabs. Unfortunately, we do not have experimental data in this pulse regime. Any information given below is not guaranteed since we do not have the appropriate source to test. General guidelines related to this specific pulse condition are the following: 1. Upper-state lifetime of Yb is in ms range according to literature. Exact lifetime of this particular Yb-doped fiber is unknown as this depends on concentration and other factors in the host glass. Assuming the lifetime is around a ms, both 10 kHz and 100 kHz should be fast enough such that the amplifier gain saturation does not recover in between pulses. Hence, the amplifier would respond to the average power at the input. 2. With the argument in 1, the gain of the amplifier would saturate based on the input average power. If input average power is around -20 dBm (calculated based on pulse width, rep rate and peak power), the system should provide the 22 dB gain at 1050 nm. 3. One key parameter to watch for here is the output peak power. Our components are rated to max peak power of 500 W. A higher peak power can cause damage to the components, although this is somewhat dependent on pulse energy as well. 4. In this pulse regime, one should also be very careful with ASE noise coming out of the amplifier. The system produces 20-30 mW of ASE power with zero input. That means, when seeded with low input average powers (below ~ -15 dBm), a good portion of the output power will consist of ASE. The easiest way to minimize the impact of that is to use a narrow-band filter at the signal wavelength to remove the out-of-band ASE. For example, a 0.1 nm filter would easily pass the ns pulses through, but will eliminate > 99% of the ASE.

Vasili Savitski (posted 2019-11-25 13:59:26.367)

Dear Sir/Madam, I have a question about your Yb-doped amplifier (YDFA100P or -S). Would it be possible to use it for amplification of pulsed emission at 1064 nm with the pulse duration of 5 ns, repetition rate of 4 MHz and average power of 3mW? The emission linewidth is 0.15 nm. What sort of output powers may I expect in the output, if the amplifier is suitable for this task? Thank you. Vasili.

llamb (posted 2019-12-02 09:54:27.0)

Hello Vasili, thank you for your feedback. Our Yb-doped amplifiers will indeed work well for the input you have described. The output average power will be around 20 dBm (100 mW) with this input.

kkmion (posted 2018-08-27 22:34:52.53)

Can the output power up to 30dBm?

YLohia (posted 2018-08-29 10:57:44.0)

Hello, the absolute maximum output power is 23 dBm so, unfortunately, it cannot output 30 dBm.