Click to Enlarge
Top View Showing Power Range Adjustment Switch

Features

Reduces Laser Intensity Noise at Frequencies from DC to 2.5 kHz
Also Functions as a Variable Optical Attenuator
Models for use at 425 - 650 nm, 650 - 1100 nm, or 1050 - 1620 nm
Max Input Power of 26 – 100 mW, Depending on Wavelength
(See the Operation Tab for Details)
Excellent for Sensitive Experiments such as Optical Tweezers
Ideal for Stabilizing CW Pump Lasers

Thorlabs’ new Liquid Crystal Noise Eaters / Laser Amplitude Stabilizers are precision instruments for stabilizing, modulating, and attenuating the power of linearly polarized light. These closed-loop systems are designed for use with light in the 425 - 650 nm (LCC3111), 650 - 1100 nm (LCC3112), or 1050 - 1620 nm (LCC3113) wavelength range.

Utilizing a liquid crystal amplitude modulator, combined with a photodiode for power measurement and a feedback control circuit, the Noise Eaters can eliminate intensity noise in linearly polarized light, achieving amplitude stabilization of within 0.05% of a selected output power. The input power can be set to one of four ranges using the switch on the top of the unit. The potentiometer is then adjusted to select the output power (see the Operation tab for more information). Long-term performance and frequency characterization for each noise eater model are shown on the Performance tabs.

These Noise Eaters are also capable of continuously attenuating the laser output using the liquid crystal retarder and integrated polarizer. Unlike most attenuators available, Noise Eaters attenuate the laser power rapidly without the use of any mechanical components. The Noise Eater’s attenuation capabilities can be controlled via the onboard potentiometer.

Thorlabs’ Noise Eaters are post mountable in two orientations via 8-32 (M4) tapped holes. They also feature 4-40 tapped holes on the front and back for 30 mm Cage System compatibility and a SM1-threaded (1.035"-40) rear aperture for Ø1" Lens-Tube compatibility.

Item #	LCC3111(/M)	LCC3112(/M)	LCC3113(/M)
Wavelength Range	425 - 650 nm	650 - 1100 nm	1050 - 1620 nm
Output Power Stability^a	±0.05%
Noise Attenuation Frequency Range	DC - 2.5 kHz
Noise Attenuation Amplitude Range	0.1% to 50% of Input Signal
Noise Attenuation Factor^b	>100 at 10 Hz 40 at 60 Hz 10 at 400 Hz 4 at 1 kHz
Transmission (Click for Plot)	>85% at 650 nm	>85% at 780 nm	>85% at 1550 nm
Maximum Input Power	30 mW^c
Minimum Input Power	0.5 mW
Damage Threshold (CW)	0.8 W/cm² at 633 nm	8 W/cm² at 780 nm	8 W/cm² at 1550 nm
Output Power Attenuation Factor Range^d	1 - 40	1 - 5	1 - 10
Input Aperture	Ø5 mm
Input Beam Diameter	Ø4 mm (Max)^e
Output Beam Displacement	1 mm Vertically (in the Direction of Input Polarization)
Beam Divergence	5 mrad (Max)
Angle of Incidence	±2° (Max)
Input Polarization Tolerance	±3°
Wavefront Distortion	≤λ/4 at 635 nm	≤λ/2 at 635 nm	≤λ/2 at 635 nm
AR Coating	R_avg <0.5% from 400 - 650 nm	R_avg <0.5% from 650 - 1100 nm	R_avg <0.5% from 1050 - 1620 nm
Attenuation Control	Onboard Potentiometer (10 Turns)
Mounting Options	Two 8-32 (M4) Tapped Holes for Post Mounting 30 mm Cage System Compatible Ø1" Lens Tube Compatible
Operating Temperature Range	15 °C to 45 °C

RMS value over 8 hours.
Tested at 3 mW input power with a noise amplitude of 5% of the input power level. See detailed noise attenuation plots on the Performance tabs for more information.
Specified at 635 nm (LCC3111), 780 nm (LCC3112), or 1550 nm (LCC3113). The actual maximum input power will vary based on the input wavelength. See the Operation tab for details. Custom versions with up to 100 mW/mm² input power capabilities are available. Contact techsupport@thorlabs.com for details.
Range of output power adjustment for a given input power level.
Specified for a 1/e² beam diameter.

Click to Enlarge
All noise eater models have an identical case and physical dimensions. The LCC3111/M, LCC3112/M, and LCC3113/M have M4-tapped holes instead of 8-32 tapped holes.

Consistent Performance at a Variety of Input Power Levels

In the graph below, the attenuation factor was measured for several different input power levels, with a signal modulation depth (noise amplitude) of 8% of the input signal. The graph below shows that the noise eater provides consistent performance regardless of input power level.

Click Icons to View Individual Plots*
0.5 mW Input Power
1.0 mW Input Power
1.5 mW Input Power
3.0 mW Input Power
5.0 mW Input Power
10 mW Input Power

*All plots are for 635 nm, 8% signal modulation.
Click to Download Raw Data

Noise Eater Attenuation at Various Input Powers

Click to Enlarge

Consistent Performance at a Variety of Noise Levels

In the graph below, the input signal was modulated with a sine wave to simulate noise. The attenuation factor was measured at a variety of modulation depths (noise amplitudes). The graph below shows that the noise eater provides consistent performance even at large noise levels.

Click Icons to View Individual Plots*
5% Signal Modulation
10% Signal Modulation
15% Signal Modulation
20% Signal Modulation
30% Signal Modulation

*Plots are for 635 nm, 3 mW input power.
Click to Download Raw Data

Click to Enlarge

Consistent Performance without Severe Signal Attenuation

Since the noise eater uses a liquid crystal modulator as the optical control element, the noise attenuation is achieved by attenuating the laser beam when noise appears. Our noise eater is carefully designed to optimize the noise attenuation performance without needing to severely attenuate the signal. The graph below demonstrates that the specified noise attenuation can be reached with a cost of only 5% to the output power, and further increase in the losses does not significantly improve the noise attenuation.

Click Icons to View Individual Plots*
5% Signal Attenuation Level
10% Signal Attenuation Level
20% Signal Attenuation Level
40% Signal Attenuation Level
60% Signal Attenuation Level
70% Signal Attenuation Level

*All plots are for 635 nm, 3 mW input power.
Click to Download Raw Data

Click to Enlarge

Click to Enlarge
Click to Download Raw Data

Click to Enlarge
Click to Download Raw Data

Consistent Performance at a Variety of Input Power Levels

In the graph below, the attenuation factor was measured for several different input power levels, with a signal modulation depth (noise amplitude) of 5% of the input signal. The graph below shows that the noise eater provides consistent performance regardless of input power level.

Click Icons to View Individual Plots*
0.5 mW Input Power
1.0 mW Input Power
1.5 mW Input Power
3.0 mW Input Power
5.0 mW Input Power
10 mW Input Power

*All plots are for 785 nm, 5% signal modulation.
Click to Download Raw Data

Click to Enlarge

Consistent Performance at a Variety of Noise Levels

Click Icons to View Individual Plots*
5% Signal Modulation
10% Signal Modulation
15% Signal Modulation
20% Signal Modulation
30% Signal Modulation

*Plots are for 785 nm, 3 mW input power.
Click to Download Raw Data

Click to Enlarge

Consistent Performance without Severe Signal Attenuation

Click Icons to View Individual Plots*
5% Signal Attenuation Level
10% Signal Attenuation Level
20% Signal Attenuation Level
30% Signal Attenuation Level
40% Signal Attenuation Level
50% Signal Attenuation Level
60% Signal Attenuation Level
70% Signal Attenuation Level

*All plots are for 785 nm, 3 mW input power.
Click to Download Raw Data

Click to Enlarge

Click to Enlarge
Click to Download Raw Data

Consistent Performance at a Variety of Input Power Levels

Click Icons to View Individual Plots*
0.5 mW Input Power
1.0 mW Input Power
1.5 mW Input Power
3.0 mW Input Power
5.0 mW Input Power
10 mW Input Power

*All plots are for 1550 nm, 5% signal modulation.
Click to Download Raw Data

Click to Enlarge

Consistent Performance at a Variety of Noise Levels

Click Icons to View Individual Plots*
3% Signal Modulation
5% Signal Modulation
10% Signal Modulation
15% Signal Modulation
20% Signal Modulation

*Plots are for 1550 nm, 3 mW input power.
Click to Download Raw Data

Click to Enlarge

Consistent Performance without Severe Signal Attenuation

Click Icons to View Individual Plots*
5% Signal Attenuation Level
10% Signal Attenuation Level
20% Signal Attenuation Level
30% Signal Attenuation Level
40% Signal Attenuation Level
50% Signal Attenuation Level
60% Signal Attenuation Level
70% Signal Attenuation Level

*All plots are for 1550 nm, 3 mW input power.
Click to Download Raw Data

Click to Enlarge

Click to Enlarge
Click to Download Raw Data

Click to Enlarge

Noise Eater Operation

Thorlabs’ Liquid Crystal Noise Eater is a precision instrument for stabilizing and attenuating laser power. The noise eater consists of a variable attenuator (liquid crystal wave plate and polarizer), a calibrated beamsplitter, and a servo controller to control the modulator, as depicted in the block diagram to the right.

Linearly polarized light is input into the liquid crystal retarder, which, together with the output polarizer, acts as a variable retarder. A beamsplitter then sends a small part of the beam to a feedback loop consisting of a photodiode and control servo. The servo compares the optical signal to a preset signal level and applies the appropriate adjustment voltage until the optical signal reaches the desired level.

The noise eater can also be used as a variable attenuator, even without the presence of noise. By adjusting the resistance of the potentiometer, the user can set the desired output power level.

Click to Enlarge
The Noise Eater can be post mounted in two different orientations to match the input light's direction of polarization. A CRM1 Cage Rotation Mount and four ER2 Cage Rods can mount a half waveplate for fine tuning the polarization alignment.

Mounting and Alignment

The noise eater is designed to work with linearly polarized input light aligned with the direction of the arrow engraved on the noise eater near the input aperture. Linearly polarized light and proper alignment of the direction of polarization are important for achieving the best results from the noise eater.

In order to minimize optical losses, the noise eater does not have an input polarizer. If the incident light is not linearly polarized, a linear polarizer (such as our LPVIS or LPNIR polarizers) before the noise eater will polarize the incident light.

If the incident light is linearly polarized but is not aligned exactly vertically or horizontally, a half-wave plate can be used before the noise eater to rotate the polarization axis. As shown in the photo to the right, the noise eater’s cage mount can be used along with a CRM1 cage rotation mount to rotate the half-wave plate, thus aligning the polarization axis with the noise eater.

For post mounting, the noise eater is equipped with two 8-32 (M4) threaded holes. These holes are offset by 90° so that light with a vertical or horizontal polarization axis can be aligned with the noise eater. The four 4-40 holes on the front of the noise eater can also be used to mount the noise eater in either a horizontal or vertical orientation using the Thorlabs 30 mm Cage System.

For best performance of the noise eater, it is recommended that the beam is well centered in the input aperture. Due to the optical path inside the noise eater, the output beam will be shifted down by 1.0 mm if the noise eater is mounted vertically.

Click to Enlarge
Top View Showing Power Range Adjustment Switch

Noise Eater Feedback Detector Normalized Responsivity

Click to Enlarge

Operation

Selecting the Power Range
The selection switch at the top of the noise eater is used to select the input power range. The power selector should be set to the lowest value that is still higher than the actual power of your laser. For example, if you are using the LCC3111 and your beam power is 8 mW at 635 nm, set the selector to 10 mW.

The LCC3111 and LCC3112 noise eaters use a Silicon detector as part of the feedback loop, while the LCC3113 uses a Germanium detector. The responsivity of the detectors is different for different wavelengths, and so the power settings on the selector only correspond to the design wavelength of the detector (635 nm for LCC3111, 780 nm for LCC3112, 1550 nm for the LCC3113). The power range at a given wavelength is inversely proportional to the responsivity (a higher responsivity value will result in a lower power range value). The graph to the right shows the relative responsivity of both detectors at a range of wavelengths. The tables below show a rough estimate of the power settings at various wavelengths for each model.

The noise eater operates by varying how much of the signal is attenuated in order to reach the target output power and attenuate the noise. Since the noise eater can attenuate the signal but not amplify it, the clean output beam can only have a power as high as the minimum power level of the noisy signal. In practice, to remove all noise without unnecessarily attenuating the signal power, the output power level should be set to slightly lower than the minimum power of the noisy signal. See the operating manual on the Documents & Drawings tab for more information.

LCC3111 Power Ranges at Various Wavelengths
Power Level at 450 nm*	Power Level at 550 nm**	Power Level at 635 nm (Marked on Noise Eater)
2 mW	1.5 mW	1 mW
6 mW	4.5 mW	3 mW
20 mW	15 mW	10 mW
60 mW	45 mW	30 mW

*For 450 nm light, the values will be ~100% higher than marked.
**For 550 nm light, the values will be ~50% higher than marked.

LCC3112 Power Ranges at Various Wavelengths
Power Level at 650 nm	Power Level at 700 nm	Power Level at 780 nm (Marked on Noise Eater)	Power Level at 900 nm	Power Level at 1000 nm	Power Level at 1100 nm
1.2 mW	1.1 mW	1 mW	0.9 mW	0.9 mW	3.3 mW
3.5 mW	3.3 mW	3 mW	2.6 mW	2.7 mW	10.0 mW
11.8 mW	11.1 mW	10 mW	8.8 mW	8.9 mW	33.3 mW
35.5 mW	33.3 mW	30 mW	26.3 mW	26.8 mW	100.0 mW

LCC3113 Power Ranges at Various Wavelengths
Power Level at 1050 nm	Power Level at 1150 nm	Power Level at 1250 nm	Power Level at 1350 nm	Power Level at 1450 nm	Power Level at 1550 nm (Marked on Noise Eater)	Power Level at 1620 nm
1.9 mW	1.6 mW	1.4 mW	1.2 mW	1.0 mW	1 mW	1.6 mW
5.8 mW	4.8 mW	4.1 mW	3.5 mW	3.1 mW	3 mW	4.8 mW
19.2 mW	16.0 mW	13.7 mW	11.7 mW	10.4 mW	10 mW	16.0 mW
57.6 mW	48.0 mW	41.1 mW	35.1 mW	31.3 mW	30 mW	48.0 mW

Please Give Us Your Feedback

Email		Feedback On
(Optional)
Contact Me:
Your email address will NOT be displayed.

Please type the following key into the field to submit this form:

Click Here if you can not read the security code.
This code is to prevent automated spamming of our site
Thank you for your understanding.

Would this product be useful to you? Little Use 1 2 3 4Very Useful

Enter Comments Below:

Characters remaining 8000

Posted Comments:

Poster: tcohen

Posted Date: 2012-11-12 13:05:00.0

Response from Tim at Thorlabs to Gediminas: Thank you for contacting us! A 650-1100nm edition of our noise eater is currently in the works and will be released shortly. For your review, we will contact you with more information on this new product.

Poster: gediminas.dauderis

Posted Date: 2012-11-12 02:01:19.23

Dear Sir/Madan, Do you have some equipment like Liquid Crystal Noise Eater / Laser Stabilizer 1000 nm wavelength? Yours Faithfully, Gediminas Dauderis

Poster: tcohen

Posted Date: 2012-11-07 21:29:00.0

Response from Tim at Thorlabs: This is correct. The noise attenuation falls off as frequency increases in the target bandwidth to 2.5kHz for this LC design. If you would be interested in a high bandwidth design we would love to discuss this with you as a possible future customer inspired product.

Poster: mlau

Posted Date: 2012-10-31 21:15:06.233

If I'm reading the noise eater specs correctly, the attentuation falls with high frequency? Is that right?

Poster: tcohen

Posted Date: 2012-07-09 13:06:00.0

Response from Tim at Thorlabs: The Noise Eater will be released soon. We should be able to assemble a 100mW version but the max beam diameter for this version is 4mm.

Poster: john.burke

Posted Date: 2012-07-05 18:41:06.0

When will this be available? Is there any chance I could get a custom one with a larger aperature and power handling? I need about 100 mW so an aperature twice radius should be helpful. I could be willing to sacrifice bandwidth for long term stability and power handling. Thanks!

Click on any phrase below to search our site using our new Search Engine:

amplitude attenuate attenuator beam control controlled crystal eater electric electrically electro electro-optic feedback filter intensity laser lc liquid loop noise noisy optic optical pid stabilization stabilize stabilizer stable trap trapping tweezer variable

View All »Matching Part Numbers

Liquid Crystal Noise Eaters / Laser Amplitude Stabilizers

Features

Consistent Performance at a Variety of Input Power Levels

Consistent Performance at a Variety of Noise Levels

Consistent Performance without Severe Signal Attenuation

Consistent Performance at a Variety of Input Power Levels

Consistent Performance at a Variety of Noise Levels

Consistent Performance without Severe Signal Attenuation

Consistent Performance at a Variety of Input Power Levels

Consistent Performance at a Variety of Noise Levels

Consistent Performance without Severe Signal Attenuation

Noise Eater Operation

Mounting and Alignment

Operation