Short-wave infrared (SWIR) imaging has become an increasingly important technology in industrial machine vision. Operating in the wavelength range between approximately 900 nm and 1700 nm, SWIR cameras reveal material characteristics and details that are invisible to standard cameras. This unique capability makes SWIR imaging a powerful tool for inspection, sorting, and analysis across a wide range of industries.
As manufacturing processes become more complex and quality requirements more stringent, SWIR cameras are enabling new inspection possibilities that were previously difficult or impossible to achieve with conventional imaging technologies.
Different objects are transparent at different wavelengths. Meat is transparent to X-rays; bones are not. Water is transparent to visible light, but not to SWIR. Materials can behave very differently at different wavelengths. For example, water is transparent to visible light but absorbs SWIR, while silicon absorbs visible light but is transparent to SWIR. Items that look similar in visible light can be very different in SWIR.
For example, plastics that appear to be the same color to the human eye can be easily differentiated in SWIR, and the absorption bands of water make moisture levels clearly visible -areas appear darker the more moisture they contain. These characteristics allow SWIR cameras to detect features and defects that are hidden from RGB or monochrome sensors.
As SWIR interacts differently than visible light, it can be used to distinguish between objects. This makes SWIR cameras particularly effective for differentiating between similar-looking substances such as:
SWIR light penetrates smoke, haze, dust, and some packaging materials better than visible light due to its longer wavelength. This makes SWIR imaging suitable for challenging environments where standard cameras struggle.
Water strongly absorbs SWIR wavelengths, enabling precise detection of moisture, wet spots, and contamination. Adding a optical filter to the camera that matches the absorption lines of water can make it clearly detectable and measure moisture levels in objects. This is especially valuable in food processing and drying processes.
Most industrial SWIR cameras use InGaAs (Indium Gallium Arsenide) sensors, as silicon is transparent to SWIR light, which offer:
SWIR cameras are available in area scan and line scan formats, enabling their use in both static inspection and high-speed continuous processes such as web inspection or free-fall sorting.
Applications for SWIR Cameras
SWIR imaging plays a crucial role in food quality control by revealing characteristics that are invisible in visible light.
Typical food inspection applications include:
In semiconductor manufacturing, SWIR cameras are used to inspect through silicon that is partially transparent in this range.
Applications include:
SWIR wavelengths allow inspection through silicon, adhesives, and some encapsulation layers, making them valuable for advanced electronics production.
Material identification is another strong use case for SWIR imaging.
SWIR cameras enable:
By improving sorting accuracy, SWIR-based systems help increase material recovery rates and improve sustainability.
In pharmaceutical production, SWIR cameras support:
SWIR imaging provides non-contact, real-time inspection that supports strict regulatory and quality requirements.
In continuous production processes such as paper, film, or textile manufacturing, SWIR line scan cameras are used to inspect:
SWIR imaging provides consistent results at high speeds, even in demanding industrial environments.
When selecting a SWIR camera, key considerations include:
Working closely with a camera manufacturer experienced in industrial SWIR applications helps ensure optimal performance and long-term reliability.
As sensor technology continues to evolve, SWIR cameras are becoming more accessible, higher in resolution, and easier to integrate into industrial systems. At the same time, advances in SWIR illumination - particularly more powerful, stable, and cost-effective LED light sources - are improving image quality and enabling more reliable inspection in production environments. Improvements in optics and data processing are further expanding the range of applications where SWIR imaging delivers measurable value.
In parallel, new sensor technologies such as organic photoconductive sensors, colloidal quantum dot (CQD) sensors, and modified CMOS-based SWIR sensors are broadening the technological landscape. These developments promise lower prices, extended wavelength coverage, and more scalable manufacturing approaches, accelerating adoption across industries.
From food safety and sustainability to semiconductor manufacturing, advanced material inspection, and recycling, SWIR cameras are transforming how manufacturers see and understand their products.
SWIR cameras open a new dimension in machine vision by revealing material properties that can't be detected by conventional imaging. Their ability to detect moisture, differentiate materials, and inspect beneath the surface makes them indispensable in many modern industrial applications.
As inspection challenges grow more complex, SWIR imaging provides manufacturers with another valuable tool to improve quality, efficiency, and process control, making it a key technology in the future of industrial vision systems.