Our collimator systems are designed with exceptional versatility, not constrained by the dimensions or optical properties of material blanks such as refractive index, uniformity, or imperfections like stripes or bubbles. Typically, they are constructed from high-performance materials like Fused Silica and Zerodur. For specialized applications, materials such as aluminum or silicon carbide (SiC) may also be used.

These systems accommodate a wide range of operational frequencies and are free from chromatic aberration, making them suitable for use across the ultraviolet (UV) to long-wave infrared (LWIR) spectrum. With the incorporation of aspheric components, they can achieve high-precision performance for large-aperture systems (up to 1.5 meters) and long focal lengths (ranging from several tens of meters to over a hundred meters). System precision can reach up to RMS values better than λ/25 @ 632.8 nm.

Depending on the required field of view, precision, and system size, various optical configurations such as Newtonian, Cassegrain, Ritchey-Chrétien (RC) reflectors, multi-reflection, or spherical reflection designs can be employed. Systems may be configured as either coaxial or off-axis, depending on the application’s need for optical shielding.

A range of metal coatings (aluminum, silver, or gold) and dielectric coatings are available, with power handling capabilities of up to 100 W/cm² for metal coatings and up to 30 kW/cm² for dielectric coatings, depending on the desired reflectance and laser damage threshold (LDT).

For special applications, our collimator systems also feature lightweight design options, providing enhanced functionality without compromising durability.

Our collimator systems are designed with exceptional versatility, not constrained by the dimensions or optical properties of material blanks such as refractive index, uniformity, or imperfections like stripes or bubbles. Typically, they are constructed from high-performance materials like Fused Silica and Zerodur. For specialized applications, materials such as aluminum or silicon carbide (SiC) may also be used.

These systems accommodate a wide range of operational frequencies and are free from chromatic aberration, making them suitable for use across the ultraviolet (UV) to long-wave infrared (LWIR) spectrum. With the incorporation of aspheric components, they can achieve high-precision performance for large-aperture systems (up to 1.5 meters) and long focal lengths (ranging from several tens of meters to over a hundred meters). System precision can reach up to RMS values better than λ/25 @ 632.8 nm.

Depending on the required field of view, precision, and system size, various optical configurations such as Newtonian, Cassegrain, Ritchey-Chrétien (RC) reflectors, multi-reflection, or spherical reflection designs can be employed. Systems may be configured as either coaxial or off-axis, depending on the application’s need for optical shielding.

A range of metal coatings (aluminum, silver, or gold) and dielectric coatings are available, with power handling capabilities of up to 100 W/cm² for metal coatings and up to 30 kW/cm² for dielectric coatings, depending on the desired reflectance and laser damage threshold (LDT).

For special applications, our collimator systems also feature lightweight design options, providing enhanced functionality without compromising durability.

Our collimator systems are designed with exceptional versatility, not constrained by the dimensions or optical properties of material blanks such as refractive index, uniformity, or imperfections like stripes or bubbles. Typically, they are constructed from high-performance materials like Fused Silica and Zerodur. For specialized applications, materials such as aluminum or silicon carbide (SiC) may also be used.

These systems accommodate a wide range of operational frequencies and are free from chromatic aberration, making them suitable for use across the ultraviolet (UV) to long-wave infrared (LWIR) spectrum. With the incorporation of aspheric components, they can achieve high-precision performance for large-aperture systems (up to 1.5 meters) and long focal lengths (ranging from several tens of meters to over a hundred meters). System precision can reach up to RMS values better than λ/25 @ 632.8 nm.

Depending on the required field of view, precision, and system size, various optical configurations such as Newtonian, Cassegrain, Ritchey-Chrétien (RC) reflectors, multi-reflection, or spherical reflection designs can be employed. Systems may be configured as either coaxial or off-axis, depending on the application’s need for optical shielding.

A range of metal coatings (aluminum, silver, or gold) and dielectric coatings are available, with power handling capabilities of up to 100 W/cm² for metal coatings and up to 30 kW/cm² for dielectric coatings, depending on the desired reflectance and laser damage threshold (LDT).

For special applications, our collimator systems also feature lightweight design options, providing enhanced functionality without compromising durability.

Our collimator systems are designed with exceptional versatility, not constrained by the dimensions or optical properties of material blanks such as refractive index, uniformity, or imperfections like stripes or bubbles. Typically, they are constructed from high-performance materials like Fused Silica and Zerodur. For specialized applications, materials such as aluminum or silicon carbide (SiC) may also be used.

These systems accommodate a wide range of operational frequencies and are free from chromatic aberration, making them suitable for use across the ultraviolet (UV) to long-wave infrared (LWIR) spectrum. With the incorporation of aspheric components, they can achieve high-precision performance for large-aperture systems (up to 1.5 meters) and long focal lengths (ranging from several tens of meters to over a hundred meters). System precision can reach up to RMS values better than λ/25 @ 632.8 nm.

Depending on the required field of view, precision, and system size, various optical configurations such as Newtonian, Cassegrain, Ritchey-Chrétien (RC) reflectors, multi-reflection, or spherical reflection designs can be employed. Systems may be configured as either coaxial or off-axis, depending on the application’s need for optical shielding.

A range of metal coatings (aluminum, silver, or gold) and dielectric coatings are available, with power handling capabilities of up to 100 W/cm² for metal coatings and up to 30 kW/cm² for dielectric coatings, depending on the desired reflectance and laser damage threshold (LDT).

For special applications, our collimator systems also feature lightweight design options, providing enhanced functionality without compromising durability.

Our collimator systems are designed with exceptional versatility, not constrained by the dimensions or optical properties of material blanks such as refractive index, uniformity, or imperfections like stripes or bubbles. Typically, they are constructed from high-performance materials like Fused Silica and Zerodur. For specialized applications, materials such as aluminum or silicon carbide (SiC) may also be used.

These systems accommodate a wide range of operational frequencies and are free from chromatic aberration, making them suitable for use across the ultraviolet (UV) to long-wave infrared (LWIR) spectrum. With the incorporation of aspheric components, they can achieve high-precision performance for large-aperture systems (up to 1.5 meters) and long focal lengths (ranging from several tens of meters to over a hundred meters). System precision can reach up to RMS values better than λ/25 @ 632.8 nm.

Depending on the required field of view, precision, and system size, various optical configurations such as Newtonian, Cassegrain, Ritchey-Chrétien (RC) reflectors, multi-reflection, or spherical reflection designs can be employed. Systems may be configured as either coaxial or off-axis, depending on the application’s need for optical shielding.

A range of metal coatings (aluminum, silver, or gold) and dielectric coatings are available, with power handling capabilities of up to 100 W/cm² for metal coatings and up to 30 kW/cm² for dielectric coatings, depending on the desired reflectance and laser damage threshold (LDT).

For special applications, our collimator systems also feature lightweight design options, providing enhanced functionality without compromising durability.

Our collimator systems are designed with exceptional versatility, not constrained by the dimensions or optical properties of material blanks such as refractive index, uniformity, or imperfections like stripes or bubbles. Typically, they are constructed from high-performance materials like Fused Silica and Zerodur. For specialized applications, materials such as aluminum or silicon carbide (SiC) may also be used.

These systems accommodate a wide range of operational frequencies and are free from chromatic aberration, making them suitable for use across the ultraviolet (UV) to long-wave infrared (LWIR) spectrum. With the incorporation of aspheric components, they can achieve high-precision performance for large-aperture systems (up to 1.5 meters) and long focal lengths (ranging from several tens of meters to over a hundred meters). System precision can reach up to RMS values better than λ/25 @ 632.8 nm.

Depending on the required field of view, precision, and system size, various optical configurations such as Newtonian, Cassegrain, Ritchey-Chrétien (RC) reflectors, multi-reflection, or spherical reflection designs can be employed. Systems may be configured as either coaxial or off-axis, depending on the application’s need for optical shielding.

A range of metal coatings (aluminum, silver, or gold) and dielectric coatings are available, with power handling capabilities of up to 100 W/cm² for metal coatings and up to 30 kW/cm² for dielectric coatings, depending on the desired reflectance and laser damage threshold (LDT).

For special applications, our collimator systems also feature lightweight design options, providing enhanced functionality without compromising durability.

Our collimator systems are designed with exceptional versatility, not constrained by the dimensions or optical properties of material blanks such as refractive index, uniformity, or imperfections like stripes or bubbles. Typically, they are constructed from high-performance materials like Fused Silica and Zerodur. For specialized applications, materials such as aluminum or silicon carbide (SiC) may also be used.

These systems accommodate a wide range of operational frequencies and are free from chromatic aberration, making them suitable for use across the ultraviolet (UV) to long-wave infrared (LWIR) spectrum. With the incorporation of aspheric components, they can achieve high-precision performance for large-aperture systems (up to 1.5 meters) and long focal lengths (ranging from several tens of meters to over a hundred meters). System precision can reach up to RMS values better than λ/25 @ 632.8 nm.

Depending on the required field of view, precision, and system size, various optical configurations such as Newtonian, Cassegrain, Ritchey-Chrétien (RC) reflectors, multi-reflection, or spherical reflection designs can be employed. Systems may be configured as either coaxial or off-axis, depending on the application’s need for optical shielding.

A range of metal coatings (aluminum, silver, or gold) and dielectric coatings are available, with power handling capabilities of up to 100 W/cm² for metal coatings and up to 30 kW/cm² for dielectric coatings, depending on the desired reflectance and laser damage threshold (LDT).

For special applications, our collimator systems also feature lightweight design options, providing enhanced functionality without compromising durability.

Our collimator systems are designed with exceptional versatility, not constrained by the dimensions or optical properties of material blanks such as refractive index, uniformity, or imperfections like stripes or bubbles. Typically, they are constructed from high-performance materials like Fused Silica and Zerodur. For specialized applications, materials such as aluminum or silicon carbide (SiC) may also be used.

These systems accommodate a wide range of operational frequencies and are free from chromatic aberration, making them suitable for use across the ultraviolet (UV) to long-wave infrared (LWIR) spectrum. With the incorporation of aspheric components, they can achieve high-precision performance for large-aperture systems (up to 1.5 meters) and long focal lengths (ranging from several tens of meters to over a hundred meters). System precision can reach up to RMS values better than λ/25 @ 632.8 nm.

Depending on the required field of view, precision, and system size, various optical configurations such as Newtonian, Cassegrain, Ritchey-Chrétien (RC) reflectors, multi-reflection, or spherical reflection designs can be employed. Systems may be configured as either coaxial or off-axis, depending on the application’s need for optical shielding.

A range of metal coatings (aluminum, silver, or gold) and dielectric coatings are available, with power handling capabilities of up to 100 W/cm² for metal coatings and up to 30 kW/cm² for dielectric coatings, depending on the desired reflectance and laser damage threshold (LDT).

For special applications, our collimator systems also feature lightweight design options, providing enhanced functionality without compromising durability.

Our collimator systems are designed with exceptional versatility, not constrained by the dimensions or optical properties of material blanks such as refractive index, uniformity, or imperfections like stripes or bubbles. Typically, they are constructed from high-performance materials like Fused Silica and Zerodur. For specialized applications, materials such as aluminum or silicon carbide (SiC) may also be used.

These systems accommodate a wide range of operational frequencies and are free from chromatic aberration, making them suitable for use across the ultraviolet (UV) to long-wave infrared (LWIR) spectrum. With the incorporation of aspheric components, they can achieve high-precision performance for large-aperture systems (up to 1.5 meters) and long focal lengths (ranging from several tens of meters to over a hundred meters). System precision can reach up to RMS values better than λ/25 @ 632.8 nm.

Depending on the required field of view, precision, and system size, various optical configurations such as Newtonian, Cassegrain, Ritchey-Chrétien (RC) reflectors, multi-reflection, or spherical reflection designs can be employed. Systems may be configured as either coaxial or off-axis, depending on the application’s need for optical shielding.

A range of metal coatings (aluminum, silver, or gold) and dielectric coatings are available, with power handling capabilities of up to 100 W/cm² for metal coatings and up to 30 kW/cm² for dielectric coatings, depending on the desired reflectance and laser damage threshold (LDT).

For special applications, our collimator systems also feature lightweight design options, providing enhanced functionality without compromising durability.

Our collimator systems are designed with exceptional versatility, not constrained by the dimensions or optical properties of material blanks such as refractive index, uniformity, or imperfections like stripes or bubbles. Typically, they are constructed from high-performance materials like Fused Silica and Zerodur. For specialized applications, materials such as aluminum or silicon carbide (SiC) may also be used.

These systems accommodate a wide range of operational frequencies and are free from chromatic aberration, making them suitable for use across the ultraviolet (UV) to long-wave infrared (LWIR) spectrum. With the incorporation of aspheric components, they can achieve high-precision performance for large-aperture systems (up to 1.5 meters) and long focal lengths (ranging from several tens of meters to over a hundred meters). System precision can reach up to RMS values better than λ/25 @ 632.8 nm.

Depending on the required field of view, precision, and system size, various optical configurations such as Newtonian, Cassegrain, Ritchey-Chrétien (RC) reflectors, multi-reflection, or spherical reflection designs can be employed. Systems may be configured as either coaxial or off-axis, depending on the application’s need for optical shielding.

A range of metal coatings (aluminum, silver, or gold) and dielectric coatings are available, with power handling capabilities of up to 100 W/cm² for metal coatings and up to 30 kW/cm² for dielectric coatings, depending on the desired reflectance and laser damage threshold (LDT).

For special applications, our collimator systems also feature lightweight design options, providing enhanced functionality without compromising durability.

Our collimator systems are designed with exceptional versatility, not constrained by the dimensions or optical properties of material blanks such as refractive index, uniformity, or imperfections like stripes or bubbles. Typically, they are constructed from high-performance materials like Fused Silica and Zerodur. For specialized applications, materials such as aluminum or silicon carbide (SiC) may also be used.

These systems accommodate a wide range of operational frequencies and are free from chromatic aberration, making them suitable for use across the ultraviolet (UV) to long-wave infrared (LWIR) spectrum. With the incorporation of aspheric components, they can achieve high-precision performance for large-aperture systems (up to 1.5 meters) and long focal lengths (ranging from several tens of meters to over a hundred meters). System precision can reach up to RMS values better than λ/25 @ 632.8 nm.

Depending on the required field of view, precision, and system size, various optical configurations such as Newtonian, Cassegrain, Ritchey-Chrétien (RC) reflectors, multi-reflection, or spherical reflection designs can be employed. Systems may be configured as either coaxial or off-axis, depending on the application’s need for optical shielding.

A range of metal coatings (aluminum, silver, or gold) and dielectric coatings are available, with power handling capabilities of up to 100 W/cm² for metal coatings and up to 30 kW/cm² for dielectric coatings, depending on the desired reflectance and laser damage threshold (LDT).

For special applications, our collimator systems also feature lightweight design options, providing enhanced functionality without compromising durability.

Our collimator systems are designed with exceptional versatility, not constrained by the dimensions or optical properties of material blanks such as refractive index, uniformity, or imperfections like stripes or bubbles. Typically, they are constructed from high-performance materials like Fused Silica and Zerodur. For specialized applications, materials such as aluminum or silicon carbide (SiC) may also be used.

These systems accommodate a wide range of operational frequencies and are free from chromatic aberration, making them suitable for use across the ultraviolet (UV) to long-wave infrared (LWIR) spectrum. With the incorporation of aspheric components, they can achieve high-precision performance for large-aperture systems (up to 1.5 meters) and long focal lengths (ranging from several tens of meters to over a hundred meters). System precision can reach up to RMS values better than λ/25 @ 632.8 nm.

Depending on the required field of view, precision, and system size, various optical configurations such as Newtonian, Cassegrain, Ritchey-Chrétien (RC) reflectors, multi-reflection, or spherical reflection designs can be employed. Systems may be configured as either coaxial or off-axis, depending on the application’s need for optical shielding.

A range of metal coatings (aluminum, silver, or gold) and dielectric coatings are available, with power handling capabilities of up to 100 W/cm² for metal coatings and up to 30 kW/cm² for dielectric coatings, depending on the desired reflectance and laser damage threshold (LDT).

For special applications, our collimator systems also feature lightweight design options, providing enhanced functionality without compromising durability.

Our collimator systems are designed with exceptional versatility, not constrained by the dimensions or optical properties of material blanks such as refractive index, uniformity, or imperfections like stripes or bubbles. Typically, they are constructed from high-performance materials like Fused Silica and Zerodur. For specialized applications, materials such as aluminum or silicon carbide (SiC) may also be used.

These systems accommodate a wide range of operational frequencies and are free from chromatic aberration, making them suitable for use across the ultraviolet (UV) to long-wave infrared (LWIR) spectrum. With the incorporation of aspheric components, they can achieve high-precision performance for large-aperture systems (up to 1.5 meters) and long focal lengths (ranging from several tens of meters to over a hundred meters). System precision can reach up to RMS values better than λ/25 @ 632.8 nm.

Depending on the required field of view, precision, and system size, various optical configurations such as Newtonian, Cassegrain, Ritchey-Chrétien (RC) reflectors, multi-reflection, or spherical reflection designs can be employed. Systems may be configured as either coaxial or off-axis, depending on the application’s need for optical shielding.

A range of metal coatings (aluminum, silver, or gold) and dielectric coatings are available, with power handling capabilities of up to 100 W/cm² for metal coatings and up to 30 kW/cm² for dielectric coatings, depending on the desired reflectance and laser damage threshold (LDT).

For special applications, our collimator systems also feature lightweight design options, providing enhanced functionality without compromising durability.

Our collimator systems are designed with exceptional versatility, not constrained by the dimensions or optical properties of material blanks such as refractive index, uniformity, or imperfections like stripes or bubbles. Typically, they are constructed from high-performance materials like Fused Silica and Zerodur. For specialized applications, materials such as aluminum or silicon carbide (SiC) may also be used.

These systems accommodate a wide range of operational frequencies and are free from chromatic aberration, making them suitable for use across the ultraviolet (UV) to long-wave infrared (LWIR) spectrum. With the incorporation of aspheric components, they can achieve high-precision performance for large-aperture systems (up to 1.5 meters) and long focal lengths (ranging from several tens of meters to over a hundred meters). System precision can reach up to RMS values better than λ/25 @ 632.8 nm.

Depending on the required field of view, precision, and system size, various optical configurations such as Newtonian, Cassegrain, Ritchey-Chrétien (RC) reflectors, multi-reflection, or spherical reflection designs can be employed. Systems may be configured as either coaxial or off-axis, depending on the application’s need for optical shielding.

A range of metal coatings (aluminum, silver, or gold) and dielectric coatings are available, with power handling capabilities of up to 100 W/cm² for metal coatings and up to 30 kW/cm² for dielectric coatings, depending on the desired reflectance and laser damage threshold (LDT).

For special applications, our collimator systems also feature lightweight design options, providing enhanced functionality without compromising durability.

Our collimator systems are designed with exceptional versatility, not constrained by the dimensions or optical properties of material blanks such as refractive index, uniformity, or imperfections like stripes or bubbles. Typically, they are constructed from high-performance materials like Fused Silica and Zerodur. For specialized applications, materials such as aluminum or silicon carbide (SiC) may also be used.

These systems accommodate a wide range of operational frequencies and are free from chromatic aberration, making them suitable for use across the ultraviolet (UV) to long-wave infrared (LWIR) spectrum. With the incorporation of aspheric components, they can achieve high-precision performance for large-aperture systems (up to 1.5 meters) and long focal lengths (ranging from several tens of meters to over a hundred meters). System precision can reach up to RMS values better than λ/25 @ 632.8 nm.

Depending on the required field of view, precision, and system size, various optical configurations such as Newtonian, Cassegrain, Ritchey-Chrétien (RC) reflectors, multi-reflection, or spherical reflection designs can be employed. Systems may be configured as either coaxial or off-axis, depending on the application’s need for optical shielding.

A range of metal coatings (aluminum, silver, or gold) and dielectric coatings are available, with power handling capabilities of up to 100 W/cm² for metal coatings and up to 30 kW/cm² for dielectric coatings, depending on the desired reflectance and laser damage threshold (LDT).

For special applications, our collimator systems also feature lightweight design options, providing enhanced functionality without compromising durability.