Infrared cut-off filter

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Infrared cut-off filter

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Infrared cut-off filters, sometimes called IR filters or heat-absorbing filters, are designed to reflect or block near-infrared wavelengths while passing visible light.^[1]^[2] They are often used in devices with bright incandescent light bulbs (such as slide and overhead projectors) to prevent unwanted heating. There are also filters which are used in solid state (CCD or CMOS) video cameras to block IR due to the high sensitivity of many camera sensors to near-infrared light. These filters typically have a blue hue to them as they also sometimes block some of the light from the longer red wavelengths.

IR transmitting/passing filters in photography

[edit]

In contrast to the naming convention of optical filters where the name of the filter denotes the wavelengths that are blocked, and in line with the convention for air filters and oil filters, photographic filters are named for the color of light they pass. Thus a blue filter makes the picture look blue. A blue filter marginally allows more light in the blue wavelength to pass resulting in a slight shift of the color temperature of the photo to a cooler color. Because of this, the term "IR filters" is commonly used to refer to filters that pass infrared light while completely blocking other wavelengths. However, in some applications the term "IR filter" still can be used as a synonym of infrared cut-off filter.

Unlike the eye, sensors based on silicon (including CCDs and CMOS sensors) have sensitivities extending into the near-infrared. Such sensors may extend to 1000 nm. Digital cameras are usually equipped with IR-blocking filters to prevent unnatural-looking images. IR-transmitting (passing) filters, or removal of factory IR-blocking filters, are commonly used in infrared photography to pass infrared light and block visible and ultraviolet light. Such filters appear black to the eye, but are transparent when viewed with an IR sensitive device.

Since the dyes in processed film block various part of visible light but are all fairly transparent to infrared, dark black sections of any processed film (where all visible colors are blocked) pass only infrared light and are commonly used (layering one over another if necessary for better visual light filtering) as a cheap alternative to expensive glass-backed filters. Such filters can be used both over color camera lenses, and to filter visible light from IR illumination sources. Such filter stock is most easily made available most simply by having any commercial color negative film developed after being fully exposed to light. The leaders of 35mm film are ideal for this, without wasting an entire roll of film. (Some special communication may be necessary in such submission, to ensure that all of the "black" negative film thus produced is indeed returned, and that there is no need to print the color-negative results on photographic paper). In the same way, visually opaque "black" color-positive film emulsions mounted in cardboard, as for routine slide projection, provide inexpensive cardboard-mounted infrared filters. Film sizes larger than 35 mm may be handled in the same way for larger filter production.

For astrophotography, many photogenic targets (such as emission nebulae) are bright in the far red and near infrared. Removal of factory filters increases sensitivity to such targets, and may also increase sharpness, as such filters may also include anti-aliasing filters.

References

[edit]

^ "IR-Cut Filter in Embedded Vision". TechNexion. Retrieved 2025-11-28.
^ Chen, Mark; Shannon, Chelsea (2020-05-31). Photography: A 21st Century Practice. Routledge. ISBN 978-1-000-18524-9.

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An infrared cut-off filter (IRCF), also known as an infrared or endothermic filter, is an optical component designed to transmit visible light wavelengths (typically 400–700 nm) while selectively blocking or attenuating infrared (IR) radiation (700 nm and beyond, often up to 2500 nm or more), thereby preventing IR interference that can distort color accuracy and image quality in sensors.^[1]^[2] These filters are essential in imaging systems because IR light, which is invisible to the human eye, can cause color shifts, haze, reduced contrast, and overheating in sensitive detectors like CCD and CMOS sensors.^[3]^[1] IR cut-off filters operate through absorption, reflection, or interference mechanisms, often employing specialized materials such as optical glass, fused quartz, or polymeric substrates coated with multi-layer dielectric films of high- and low-refractive-index materials to achieve a sharp transition between the visible transmission band and IR blocking region.^[1]^[2] They are classified by form and function, including fixed filters permanently integrated into devices for constant IR suppression and mechanical (switchable) variants, such as motorized shutters positioned between the lens and sensor, which retract during low-light conditions to allow IR for enhanced night vision while maintaining true color in daylight.^[4]^[2] Key specifications include high visible light transmittance (often >90%) and optical density (OD) greater than 3 for IR blocking, ensuring minimal light loss in the desired spectrum.^[5] These filters find widespread applications in digital and security cameras, machine vision systems, microscopy, and surveillance equipment, where they enable realistic color reproduction, protect components from thermal damage, and support true day-night (TDN) functionality for applications like automatic number plate recognition (ANPR) and video conferencing.^[4]^[1] In consumer devices such as smartphones, webcams, and automotive cameras, as well as scientific imaging and photography, IRCFs eliminate IR-induced aberrations, aligning output with human visual perception for sharper, more reliable results.^[2]^[3]

Fundamentals

Definition and Purpose

An infrared cut-off filter is an optical component designed to transmit visible light wavelengths, typically in the range of 400 to 700 nm, while attenuating or blocking infrared radiation beyond approximately 700 nm.^[1] This selective transmission prevents infrared light from reaching sensitive detectors, such as CCD or CMOS sensors, which would otherwise interpret it as visible light and cause distortions.^[6] The primary purpose of an infrared cut-off filter is to replicate the spectral response of human vision in imaging systems, where the eye naturally excludes infrared while perceiving colors in the visible spectrum.^[6] Digital sensors detect infrared radiation but lack the ability to differentiate it from visible wavelengths, leading to color shifts, washed-out images, or false hues—particularly under daylight conditions where sunlight emits significant infrared.^[6] Without this filter, uncorrected infrared exposure can overload sensors, reducing dynamic range and introducing artifacts that compromise image quality.^[1] Key benefits include enhanced image fidelity through accurate color reproduction, mitigation of heat accumulation from infrared absorption in devices, and improved overall performance in environments with high infrared content, such as outdoor or illuminated settings.^[1] A typical transmission spectrum for such a filter features a cutoff wavelength around 700 nm, with greater than 90% average transmission across the visible band (e.g., 430–615 nm) and less than 1% transmission in the near-infrared region starting at 700 nm.^[7]

Optical Principles

Infrared cut-off filters achieve wavelength selectivity by exploiting differences in light-matter interactions across the spectrum, allowing visible light (typically 400–700 nm) to transmit with minimal absorption while blocking infrared (IR) wavelengths (above ~700 nm) through either absorption or reflection mechanisms.^[1] In absorptive designs, visible photons encounter low absorption in the filter medium due to insufficient energy to excite electronic transitions, whereas IR photons possess energies that align with vibrational or electronic modes, leading to strong absorption.^[1] This selectivity ensures high transmittance in the visible range (>90% in optimized filters) and near-total blocking (optical density >6) in the near-IR, preventing IR-induced artifacts in imaging systems.^[8] The absorption mechanism in IR cut-off filters relies on IR photons being captured by the filter material, where they excite electrons or vibrational modes, converting photonic energy into heat that dissipates without re-emission in the transmission direction.^[1] Specialized glasses, such as those with embedded ions, exhibit this behavior, absorbing >90% of IR radiation from sources like tungsten-halogen lamps while passing visible light.^[1] Quantitatively, absorbance

A

quantifies this blocking and is defined by the Beer-Lambert law as

A = -\log_{10}(T)

, where

T

is the transmittance (fraction of incident light transmitted); for effective IR cut-off,

A > 3

(corresponding to

T < 0.001

) is typical in the blocked band.^[9] In interference-based IR cut-off filters, thin-film multilayer stacks create destructive interference for IR wavelengths, reflecting them away from the transmission path while allowing constructive interference for visible light.^[8] These designs typically consist of alternating high- and low-refractive-index dielectric layers (e.g., SiO

_2

/TiO

_2

) deposited on a substrate, tuned such that quarter-wave thicknesses at the cutoff wavelength produce a sharp transition.^[10] The reflection condition for periodic multilayer stacks follows Bragg's law:

m\lambda = 2 n d \sin\theta

, where

m

is the diffraction order,

\lambda

is the wavelength,

n

is the average refractive index,

d

is the layer period, and

\theta

is the angle of incidence; this governs the photonic bandgap that rejects IR while transmitting visible.^[11] Such filters achieve >90% visible transmittance and <1% IR transmittance beyond 770 nm through phase-controlled interference, without relying on material absorption.^[10] Key performance metrics for IR cut-off filters include cutoff steepness, which measures the transition sharpness from high visible transmittance to IR blocking, often achieving slopes where transmittance drops from 90% to <1% over <1% of the wavelength range via advanced coatings.^[8] Angular dependence arises from the oblique incidence effect, causing a blue shift in the cutoff wavelength approximated by

\lambda_\phi = \lambda_0 / \sqrt{n^2 - \sin^2\phi}

λϕ=λ0/n2−sin2ϕ

, where $\phi$ is the angle of incidence and $n$ is the substrate index; this shift is minor (<1 nm) up to 10° but requires design compensation for wide-field applications.^[8] Environmental stability, particularly temperature effects, involves a redshift of ~0.019 nm/°C in the cutoff due to thermal expansion of layers, with hard-coated filters showing 2–5 pm/°C shifts; operation is stable from -60°C to +60°C without significant transmission loss.^[8]^[12]

Types and Construction

Absorptive Filters

Absorptive infrared cut-off filters operate by selectively absorbing infrared radiation within the substrate material itself, rather than reflecting it away. These filters are typically constructed using glass or plastic substrates impregnated or dyed with organic compounds that exhibit strong absorption in the infrared spectrum while allowing high transmission of visible light. Common dyes include cyanine and phthalocyanine derivatives, which provide selective IR absorption due to their conjugated molecular structures.^[13]^[14] The substrate thickness is generally 1-3 mm to achieve sufficient optical path length for effective attenuation, with standard options at 1 mm, 2 mm, or 3 mm for balanced performance and manufacturability.^[15] A key advantage of absorptive filters is their simplicity and cost-effectiveness in production, as they require no complex multilayer coatings. They offer broadband IR blocking extending up to approximately 1100 nm, providing robust heat protection across a wide spectral range without the need for precise wavelength tuning. Additionally, these filters exhibit no significant angular sensitivity, maintaining consistent performance regardless of incident light angle, which simplifies integration in various optical systems.^[15]^[16] However, the absorption mechanism leads to heat generation within the filter material, as the absorbed IR energy is converted to thermal energy, potentially causing degradation over time if not managed. This thermal buildup can limit their lifespan in high-power applications, where active cooling or ventilation may be necessary to prevent warping or reduced optical quality.^[15] Representative examples include the Schott KG series of heat-absorbing glass filters, such as KG1 and KG5, which feature cutoffs between 650 nm and 750 nm (e.g., approximately 716 nm for KG1). These filters achieve average visible transmission exceeding 90% (often around 92-95% in the 400-700 nm range) and provide optical densities of about 3 in the near-IR (e.g., OD 2.5-3.0 beyond 800 nm), ensuring effective IR suppression.^[17]^[18]^[19]

Interference Filters

Interference-based infrared cut-off filters utilize multilayer dielectric coatings to selectively reflect infrared wavelengths while transmitting visible light, relying on the principle of constructive and destructive interference. These filters are constructed by depositing alternating layers of high-refractive-index materials, such as titanium dioxide (TiO₂, n ≈ 2.3–2.5), and low-refractive-index materials, like silicon dioxide (SiO₂, n ≈ 1.46), onto an optical substrate such as borosilicate glass or sapphire. The layers are typically applied using vacuum evaporation or magnetron sputtering techniques, which allow precise control over thickness and uniformity, with 10 to 50 layers often required to achieve the desired sharp cut-off edges. In quarter-wave stack designs, the central wavelength λ of the reflection peak is determined by the formula λ = 4nd/m, where n is the refractive index of the layer, d is its physical thickness, and m is an odd integer representing the order of interference. These filters exhibit several key advantages over other types, including high optical efficiency with greater than 99% reflection of infrared radiation in the blocked region, minimizing thermal effects since unwanted light is reflected rather than absorbed. They also provide steep transition edges, enabling rapid shifts from high transmission in the visible spectrum to strong blocking in the infrared, with transition widths as narrow as 5–50 nm depending on the design and number of layers. Additionally, the dielectric construction enhances durability, offering resistance to environmental factors such as humidity, thermal cycling, and mechanical stress, with adhesion strengths supporting loads up to 1.5 × 10⁴ N/m in tested configurations. However, interference filters have notable limitations, including higher manufacturing costs due to the complexity of multilayer deposition processes and the need for specialized equipment. They are sensitive to the angle of incidence, exhibiting a blue-shift in the cut-off wavelength at oblique angles (e.g., shifting toward shorter wavelengths as the angle increases from normal), which can affect performance in non-collimated light paths. Compared to absorptive alternatives, they also tend to have narrower effective bandwidths for broadband applications. Specific commercial examples include hard-coated interference IR cut-off filters from Edmund Optics, such as those with a 710 nm cut-off wavelength, designed for high transmission (>85%) from 480–680 nm and blocking (<10%) from 740–1200 nm, commonly used in imaging systems to prevent infrared-induced color distortion.

Applications

In Digital Imaging and Photography

In digital imaging and photography, infrared cut-off filters are essential components integrated directly in front of the image sensor in consumer and professional cameras, such as DSLRs and smartphones, to block unwanted infrared light and ensure accurate color reproduction when using Bayer color filter arrays. These filters correct for the inherent sensitivity of silicon-based sensors to infrared wavelengths beyond the visible spectrum, preventing IR bleed that would otherwise cause significant color shifts, such as a magenta cast.^[20]^[21] Without this filtration, the sensor's response mismatches human vision, leading to distorted hues that degrade image quality in standard daylight photography. In DSLRs from manufacturers like Canon and Nikon, the IR cut-off filter is typically a fixed optical element bonded to the low-pass filter stack over the sensor, as seen in models like the Canon EOS series and Nikon D810, where it maintains color fidelity during typical shooting conditions.^[22]^[23] Similarly, smartphone camera modules incorporate thin IR cut-off coatings or films on the sensor cover glass to achieve compact, true-color imaging without bulky external filters.^[24] The necessity for these filters in digital systems emerged prominently in the 1990s with the commercialization of charge-coupled device (CCD) sensors, which extended the spectral sensitivity of early digital cameras into the near-infrared range, unlike traditional silver-halide film emulsions that had more limited IR response. While early photographic films from the late 19th and early 20th centuries were often sensitive to infrared for specialized applications like aerial reconnaissance, the transition to digital imaging amplified the issue because CCDs and later CMOS sensors respond strongly to wavelengths up to about 1100 nm, far beyond visible light. This historical shift necessitated built-in IR cut-off filters to align digital output with perceptual color accuracy, a standard feature in cameras since early digital SLRs, such as the 1999 Nikon D1.^[25]^[26] In security and surveillance cameras, which often double as photographic devices, IR cut-off filters enable day/night switching through mechanical or motorized mechanisms that position the filter over the sensor during daylight for color imaging and retract it at low light levels to enhance infrared sensitivity for monochrome night vision. This true day/night (TDN) functionality, common in IP cameras, uses ambient light sensors to automate the flip, allowing the same device to capture vibrant daytime portraits or landscapes in color while switching seamlessly to IR-illuminated black-and-white modes after dusk without compromising overall system performance. The result is enhanced versatility in professional photography setups, such as event coverage or outdoor shoots, where true-to-life color rendition in portraits—preserving natural skin tones—and landscapes—retaining verdant greens and blue skies—is critical for visual fidelity.^[4]^[27]

In Scientific and Industrial Uses

Infrared cut-off filters play a crucial role in projectors and displays utilizing incandescent-based systems, such as overhead projectors, by blocking infrared radiation to mitigate excessive heat accumulation on optical elements like lenses. This suppression of IR helps prevent thermal damage to components and contributes to prolonging lamp lifespan through reduced operating temperatures.^[28]^[29] In medical and scientific imaging applications, these filters are integrated into endoscopes and microscopes to eliminate IR-induced fluorescence artifacts, ensuring precise visible light capture and minimizing background noise or color aberrations in diagnostic procedures. For instance, in fluorescence microscopy setups, IR cut-off filters safeguard excitation and emission filters from heat degradation while maintaining spectral integrity. Additionally, combinations of UV and IR cut-off filters enhance spectral purity in these systems, isolating the visible spectrum for accurate tissue analysis and high-fidelity imaging without extraneous wavelength interference.^[30]^[31]^[32] Industrial inspection relies on infrared cut-off filters in machine vision systems for quality control, where they block IR under LED illumination to deliver enhanced contrast and clarity, facilitating reliable defect detection on production lines without IR-related distortions. In astronomy, these filters are applied in telescope imaging to suppress atmospheric IR emissions, improving the resolution and color accuracy of celestial observations. Similarly, in drones conducting visual surveying, IR cut-off filters prevent IR interference, enabling distortion-free visible imagery for applications like infrastructure monitoring and environmental assessment.^[33]^[34]^[35]

IR-Pass Filters

IR-pass filters, also known as infrared longpass filters, are optical components engineered to transmit infrared wavelengths typically in the 700–1100 nm range while blocking visible light (400–700 nm), often achieving greater than 90% attenuation below 700 nm.^[36] Their primary purpose is to enable imaging or sensing exclusively in the infrared spectrum, eliminating interference from visible light to enhance contrast and resolution in applications such as night vision, forensic examination, and machine vision systems.^[37] By isolating IR radiation, these filters support scenarios where visible illumination is undesirable or counterproductive, such as covert operations or specialized spectral analysis.^[38] Construction of IR-pass filters commonly involves either absorptive or interference mechanisms. Absorptive types utilize dyes embedded in polymer substrates or black glass materials to selectively absorb visible light while allowing IR to pass, as seen in filters with optical densities (OD) exceeding 4.0 in the visible range for deep blocking.^[36] Interference-based designs, on the other hand, employ multilayer dielectric coatings to reflect visible wavelengths and transmit IR through constructive interference in the desired passband.^[39] A representative example is the Hoya R-72 filter, an absorptive design with a sharp cutoff at approximately 720–740 nm, providing over 95% transmission from 760–860 nm for reliable IR performance.^[38] In applications, IR-pass filters are employed in photography to create ethereal, false-color infrared landscapes with pronounced contrasts between foliage and skies, yielding artistic effects like glowing vegetation due to the Wood effect in IR reflectance.^[38] For security and surveillance, they pair with IR illuminators and monochrome sensors to enable invisible lighting for night-time monitoring, blocking visible light to maintain stealth while capturing high-contrast IR images.^[37] A key distinction from IR-cut-off filters lies in their spectral inversion: while cut-off filters remove IR to preserve visible color fidelity, IR-pass filters demand the removal or disablement of a camera's internal IR-cut filter to fully exploit sensor sensitivity in the near-IR, unlocking unique functional and aesthetic capabilities but requiring hardware modifications.^[40]

Switchable IR-Cut Systems

Switchable IR-cut systems enable imaging devices to dynamically toggle between color-accurate daytime operation and infrared-sensitive nighttime mode by mechanically or electronically inserting and removing an IR-cut filter from the optical path. These systems typically employ an electromechanical mechanism, such as a solenoid or motor-driven assembly, that slides, rotates, or flips a dual-filter stack—consisting of an IR-cut filter and a clear glass pane—into or out of position in front of the sensor. This design preserves the optical path length to avoid focus shifts between modes. Response times for such switches are generally under 50 ms, allowing seamless transitions based on ambient light levels detected by the camera's sensor.^[41]^[42]^[43] An alternative approach uses liquid crystal (LC) shutters, which electronically modulate polarization to block or transmit IR light without moving parts, offering potentially faster switching in specialized applications, though mechanical systems remain dominant in consumer and surveillance cameras due to cost and simplicity.^[44] The primary advantages of switchable IR-cut systems include the ability of a single device to deliver true-color images during the day while enabling high-sensitivity monochrome imaging at night, often paired with IR illuminators for enhanced low-light performance. This versatility has made them standard in IP cameras since the early 2000s, supporting applications like outdoor surveillance where consistent monitoring across varying lighting conditions is essential.^[27]^[42] Key design considerations focus on maintaining optical integrity and operational robustness, particularly in outdoor environments. The dual-filter stack ensures minimal parallax or defocus issues by matching thicknesses between the IR-cut filter (typically blocking wavelengths above 650 nm) and the clear substitute, while low-power solenoids (operating at 3.3-12 V DC) optimize energy efficiency. Reliability is prioritized through components rated for extended lifecycles—up to 1,000,000 cycles—and wide temperature ranges (-30°C to 80°C), with humidity tolerance up to 90% to withstand harsh conditions without mechanical failure.^[45]^[41]^[43] Specific examples include Sony's FCB series camera modules, such as the FCB-CR8530, which integrate auto ICR (IR-cut removable) functionality with CMOS sensors for automatic day/night switching in security applications. This represents an evolution from the fixed IR-cut filters prevalent in 1990s consumer digital cameras, which limited low-light versatility, to adaptive systems in the 2000s that expanded into professional surveillance and embedded vision.^[46]^[27]

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