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MWIR detector and 1280x1024 resolution for crispy image. In addition, Continuous Zoom IR Lens 40~1000mm can distinguish the human, vehicle and ships at long range.
Details Parameters
Advanced technologies for the highest performance mid-wave focal planes:
1. High-durability and hard-carbon 3.7-4.8 µm MWIR wavelength AR exposed mirror coating
2. Passive athermalization with the highest imaging performance from -40 to +60°C
3. Optimized for 1280x1024 cooled MWIR cameras with 10 μm pixel pitch
4. Motorized focus and zoom mechanism with crisp image over the full range
| Specifications | ||
| OPTICAL | ||
| Focal Length / F# | 40~1000mm F/4 | Compatible with detectors having 40mm ≥ EFL≤1000mm |
| Detector (FPA) type | 1280×1024-10μm | |
| Working Spectral Band(SR) | 3.7um-4.8um | |
| FOV | 18.18°×14.59°~0.73°×0.58° | |
| Exposed Mirror Coating | High efficiency AR coating | |
| Focus Range | 20m to infinity | |
| Cold stop to FPA Distance | 20 | We can redesign as your requirement |
| MECHANICAL | ||
| Zoom Mechanism | Motorized Adjustable | |
| FOV Switch Mechanism | Motorized Adjustable | |
| Total Weight | 14.5Kg | Including detector |
| Dimensions | Ø248mm×421.68mm | Length is available upon request |
| ENVIRONMENTAL | ||
| Operating Temperature | -40ºC to +60ºC | |
| Storage Temperature | -40ºC to +60ºC | Keep two houres when test |
| Shock and Vibrations | Per applicable standard | |
| Front Lens Sealing | IP67 | |
High Sensitivity and Long-distance Detection:The 1000mm infrared medium-wave cooled lens adopts advanced cooling technology, which significantly reduces the thermal noise of the detector and achieves extremely high sensitivity. In the medium-wave infrared band (usually 3-5 micrometers), it can accurately capture weak infrared radiation signals and clearly detect targets even at long distances (up to several kilometers). It is suitable for scenarios with strict requirements for long-distance target monitoring, such as border surveillance, forest fire prevention, and maritime search and rescue.
Excellent Imaging Quality:With its large aperture design and precise optical structure, this lens enables high-resolution imaging, effectively reducing image distortion and blurring, and presenting delicate and clear thermal images, making all target details visible. Whether it is identifying small targets or observing subtle temperature differences of targets, it can handle tasks with ease, providing users with accurate and reliable image information to assist in precise analysis and decision-making.
Strong Environmental Adaptability:It has excellent environmental adaptability and can operate stably under extreme temperatures (such as high heat and severe cold), harsh weather conditions (rain, fog, sand, and dust), and other complex environments. The characteristics of the medium-wave infrared band make it less affected by atmospheric attenuation. It still maintains good penetrability in low-visibility environments such as smoke and light fog, continuously outputting clear thermal imaging pictures to ensure uninterrupted monitoring work.
Fast Response and Accurate Temperature Measurement:The fast response characteristics of the cooled detector ensure that the lens can quickly capture the temperature changes of targets and achieve accurate temperature measurement. Through precise temperature data, potential problems such as equipment overheating and abnormal heat sources can be detected in a timely manner. It is widely used in power inspection, industrial equipment monitoring, and other fields, providing strong support for equipment maintenance and fault early warning.
Detection, Recognition & Identification (DRI) Range
DRI ranges enable one to easily estimate the maximum range that an object can be either detected, recognized or identified. It is important to note that these estimates are based solely on geometrical parameters – the target size, distance, lens focal length and camera detector pixel size. Signal level, detector sensitivity, atmospheric conditions and other factors are not considered!
Detection: An object is present – Car90km&Person20km.
Recognition: discern the type of object – Car30km&Person6.67km.
Identification: discern specific objects –Car15km&Person3.33km.
High Performance Mid-Wave Focal Plane
Passive Athermalized Lens Assembly
Using advanced technologies, top-quality materials and unique coating techniques, together with innovative engineering and opto-mechanical designs, we have earned a reputation for excellent performance, durability and quality.
FAQ
View MoreWhat is an infrared lens?
An infrared lens is a type of optical lens that is designed to focus infrared light. It is made of materials and has coatings that allow it to efficiently transmit infrared wavelengths, which are longer than those of visible light. Infrared lenses are used in various applications such as infrared cameras, thermal imaging systems, and night vision devices, enabling the capture of images in low-light or no-light conditions based on the infrared radiation emitted or reflected by objects.
What are the main applications of IR lenses?
Infrared lenses are widely used in many fields. In the field of security and surveillance, they are used in infrared cameras for night monitoring to detect intruders or monitor activities in the dark. In the military, they are used for night vision goggles and infrared detection systems to enhance situational awareness. In industry, they are applied in thermal imaging cameras for equipment inspection, detecting overheating components or heat leaks in pipelines. In addition, infrared lenses are also used in astronomy for observing celestial bodies that emit infrared radiation, and in some scientific research fields such as environmental monitoring and remote sensing.
What materials are commonly used to make IR lenses?
Common materials for infrared lenses include germanium (Ge), zinc selenide (ZnSe), and silicon (Si). Germanium is a popular choice due to its excellent infrared transmission properties in the mid-wave and long-wave infrared regions. It has a high refractive index, which allows for more compact lens designs. Zinc selenide is another commonly used material that offers good infrared transparency and is suitable for a wide range of infrared wavelengths. Silicon is also used, especially in the near-infrared range, and has the advantage of being relatively inexpensive and compatible with semiconductor manufacturing processes.
How are infrared lenses designed to handle different infrared wavelengths?
Infrared lenses are designed with materials and optical geometries that are optimized for specific infrared wavelength ranges. For example, lenses for near-infrared (NIR) applications may have different refractive indices and curvatures compared to those for mid-wave infrared (MWIR) or long-wave infrared (LWIR).
How is the performance of an IR lens evaluated?
The performance of an infrared lens is evaluated by several parameters. Modulation Transfer Function (MTF) is an important indicate that measures the lens's ability to transfer contrast from the object to the image plane at different spatial frequencies, indicating the sharpness and clarity of the image. Another parameter is the focal length, which determines the magnification and field of view of the lens. The aperture or f-number affects the amount of light that can pass through the lens and thus the brightness of the image. In addition, factors such as chromatic aberration, distortion, and the lens's ability to maintain focus over a range of temperatures also play important roles in evaluating its performance.
How to ensure the quality of infrared lenses during the manufacturing process?
During the manufacturing process of infrared lenses, strict quality control measures are essential. This includes precise grinding and polishing of the lens surfaces to achieve the required curvature and smoothness, which is crucial for accurate focusing and minimizing light scattering. High-quality coating processes are also necessary to apply anti-reflective coatings that enhance the infrared transmission and reduce unwanted reflections. Meticulous inspection and testing at each stage of production, such as using interferometers to measure surface accuracy and another testing equipment to evaluate optical performance, help to identify and correct any defects or deviations from the required specifications. Additionally, maintaining a clean and controlled manufacturing environment is important to prevent contamination that could affect th
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Application Scenario
In the aerospace field, infrared lenses play an indispensable role. Airborne night vision is one of its important applications. In addition, in satellite remote sensing, infrared lenses can penetrate clouds and obtain information such as surface temperature and vegetation cover, contributing to agricultural monitoring, geological exploration, and more. It also can detect the infrared radiation of celestial bodies like asteroids and comets.
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Infrared lens can operate in low-light or even complete darkness, using the infrared radiation emitted by objects for imaging. Moreover, they are not affected by severe weather such as heavy rain and thick fog, and can penetrate these obstacles to capture targets, ensuring the stability of monitoring, greatly enhancing the reliability and comprehensiveness of security monitoring.
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Since different materials and components in industrial settings have distinct infrared emission characteristics, these lenses enable the detection of thermal anomalies. In the manufacturing of mechanical parts, infrared lenses can detect areas with abnormal heat distribution during the production process, helping to ensure product quality and prevent defects.
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At the fire scene, infrared lenses can penetrate smoke and flames and clearly display the location of trapped persons, the direction of fire spread, and the ignition point. This helps firefighters quickly formulate rescue plans, improve search and rescue efficiency, and reduce casualties and property losses. In addition, it can also be used for fire hazard investigation to discover potential fire risks such as overheating of electrical equipment and accumulation of flammable materials in advance.
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Infrared lenses are the key components in gas detection instruments, enabling the precise identification and quantification of various industrial gases. Many industrial gases have unique absorption characteristics in the infrared spectrum.
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These lenses are designed to capture infrared radiation, which is invisible to the human eye but emitted by objects based on their heat signatures. They focus this infrared light onto an image sensor, converting it into a visible image that can be displayed on a monitor inside the vehicle. This enables drivers to perceive potential obstacles on the road much earlier than with normal vision, providing them with more reaction time and significantly enhancing driving safety in low-light conditions.
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