Many people might wonder why laser rangefinder modules come in different wavelengths. The truth is, the diversity in wavelengths arises to balance application needs with technical constraints. Laser wavelength directly affects system performance, safety, and cost. Here’s a detailed explanation of the reasons:
1. The Effect of Wavelength on Physical Characteristics of Rangefinding
(1) Atmospheric Attenuation and Transmission Performance
Laser transmission is influenced by atmospheric absorption and scattering, both of which are highly wavelength-dependent. Short Wavelengths (e.g., 532nm): experience more significant scattering (rayleigh scattering). In dusty, foggy, or rainy environments, attenuation is substantial, making them unsuitable for long-distance applications. Mid-Range Wavelengths (e.g., 808nm, 905nm): have less atmospheric absorption and scattering, making them mainstream choices for rangefinders, especially for outdoor use. Long Wavelengths (e.g., 1535nm, 1550nm): sensitive to water vapor absorption under certain conditions but exhibit low scattering and concentrated energy, suitable for long distances and specialized environments.
(2) Reflective Characteristics of Target Surfaces
The reflectivity of laser wavelengths on target surfaces impacts rangefinding performance.
Short wavelengths perform well with highly reflective targets but have low reflectivity on dark or rough surfaces. Mid-range wavelengths offer good adaptability across various materials and are common in rangefinding modules. Long Wavelengths provide better penetration on rough surfaces, making them ideal for terrain mapping and complex scenarios.
2. Eye Safety and Wavelength Selection
The human eye is highly sensitive to visible light (400-700nm) and near-infrared light (700-1000nm). Laser beams in these ranges can focus on the retina and cause damage, necessitating strict power control and limiting usage scenarios and output capacity. Long wavelengths (e.g., 1535nm, 1550nm) are safer as their energy is absorbed by the cornea and lens, preventing direct exposure to the retina. This significantly reduces safety risks, making these wavelengths valuable for military and high-power long-distance rangefinding.
3. Technical Complexity and Cost
The complexity and cost of laser rangefinder modules vary greatly depending on wavelength.
- 532nm (Green Lasers): Typically generated by frequency-doubling infrared lasers (1064nm). This process has low efficiency, high heat dissipation requirements, and high costs.
- 808nm, 905nm (Near-Infrared Lasers): Benefit from mature semiconductor laser technology, offering high efficiency and low cost, making them ideal for consumer-grade products.
- 1535nm, 1550nm (Fiber Lasers): Require specialized fiber lasers and matching detectors (e.g., InGaAs). These modules are more expensive overall.
4. Application Needs in Different Scenarios
For short-distance measurement, 532nm and 905nm are excellent choices. Although scattering effects are significant at short wavelengths, they have minimal impact over short distances. Additionally, 905nm lasers offer a balance of performance and cost, becoming a mainstream choice for rangefinder modules. For long-distance measurement: 1064nm and 1550nm wavelengths are more suitable, as longer wavelengths concentrate energy and penetrate more effectively, ideal for industrial and military applications requiring long-range and high-precision measurement. For high-light-interference environments, 1550nm wavelengths excel in such conditions, as they are less affected by sunlight interference. This ensures a high signal-to-noise ratio under strong light, making them suitable for outdoor radar and surveillance equipment.
With this explanation, you should now have a deeper understanding of why laser rangefinder modules come in different wavelengths. If you have needs for laser rangefinder modules or want to learn more, feel free to contact us anytime!
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Post time: Nov-25-2024