Meadowlark Optics’ Liquid Crystal Variable Attenuator (LCVA) offers real-time, continuous control of light intensity. Our attenuator consists of an LC Variable Retarder (with attached compensator) operating between crossed linear polarizers. With crossed polarizers, light transmission is maximized by applying the correct voltage to achieve half-wave retardance from the LC cell as shown in figure 4-11. Half-wave operation rotates the incoming polarization direction by 90°, so that light is passed by the second polarizer. Minimum transmission is obtained with the retarder operating at zero (or a whole number of) waves.
Transmission decreases as the applied AC voltage amplitude increases (half- to zero-waves retardance). The relationship between transmittance T and retardance ?(in degrees) for crossed polarizer configuration is given by: T(Θ) = 1/2 [1 - cos(Θ)] Tmax whereTmax is the maximum transmittance when retardance is exactly one-half wave (or 180°). Figure 4-12 shows transmittance as a function of applied voltage.
Read More...Meadowlark Optics’ Liquid Crystal Variable Attenuator (LCVA) offers real-time, continuous control of light intensity. Our attenuator consists of an LC Variable Retarder (with attached compensator) operating between crossed linear polarizers. With crossed polarizers, light transmission is maximized by applying the correct voltage to achieve half-wave retardance from the LC cell as shown in figure 4-11. Half-wave operation rotates the incoming polarization direction by 90°, so that light is passed by the second polarizer. Minimum transmission is obtained with the retarder operating at zero (or a whole number of) waves.
Transmission decreases as the applied AC voltage amplitude increases (half- to zero-waves retardance). The relationship between transmittance T and retardance ?(in degrees) for crossed polarizer configuration is given by: T(Θ) = 1/2 [1 - cos(Θ)] Tmax whereTmax is the maximum transmittance when retardance is exactly one-half wave (or 180°). Figure 4-12 shows transmittance as a function of applied voltage.
Maximum transmission is dependent upon properties of the LC Variable Retarder as well as the polarizers used in your system. Figure 4-13 shows the transmission of an LC Variable Attenuator optimized for use at 550 nm with crossed polarizers. An unpolarized light source is used for illumination.
Extinction ratio is defined as the maximum transmission (LC cell at half-wave) divided by the minimum transmission (LC cell at zero waves). Values exceeding 1000:1 (see figure 4-14) can be obtained for a single wavelength by optimizing the applied voltage levels for minimum and maximum transmission. We guarantee a minimum extinction ratio of 500:1 at your specified wavelength.
A Liquid Crystal Variable Attenuator can be configured with high efficiency calcite or beamsplitting polarizers to maximize light transmittance and increase damage threshold. With a linearly polarized input beam and a calcite polarizer, transmittance values exceed 90% at most wavelengths. Very high extinction ratios, in excess of 5000:1, can be achieved with custom double attenuators. In this design, two Liquid Crystal Variable Retarders are combined with three polarizers.
Read Less...Specifications - Variable Attenuator | |
Retarder Material | Nematic liquid crystal with Birefringent polymer |
Polarizer Material | Dichroic polymer |
Substrate Material | Optical quality synthetic fused silica |
Wavelength Range | |
Visible |
450-700 nm 650-950 nm 900-1250 nm 1200-1700 nm |
Contrast Ratio | 500:1 at single wavelength |
Transmitted Wavefront Distortion | ≤ λ/4 (each component) |
Surface Quality (scratch-dig) | 40-20 |
Beam Deviation | ≤ 2 arc min |
Reflectance (per surface) | ≤ 0.5% at normal incidence |
Operating Temperature | 0°C to 50°C |
Laser Damage Threshold | 1 W/cm2, CW (dichroic polarizers) |
Ordering Information - Liquid Crystal Variable Attenuator | |||
Clear Aperture in. [mm] |
Diameter ± 0.005 in. [± 0.13 mm] |
Thickness in. [mm] |
Part Number |
0.37 [9.4] |
Ø1.00 [Ø25.4] |
1.23 [31.2] |
LVA-100-λ |
0.70 [17.8] |
Ø2.00 [Ø50.8] |
0.75 [19.1] |
LVA-200-λ |
1.60 [40.6] |
Ø3.00 [Ø76.2] |
1.00 [25.4] |
LVA-300-λ |
Please specify operating wavelength λ in nanometers when placing your order. |