Get in Touch with Saiweiglass
All touch screen glass suffers from the same three enemies: the glare that overpowers the image, the reflections that conceal the display image, and the fingerprints that smudge the image after every swipe. Surface treatment technology presents a solution – anti-glare (AG), anti-reflective (AR), and anti-fingerprint (AF) coatings. Every coating address a different optical problem in a different manner, and selecting the wrong coating will create a poor display rather than a better one.
We have a lot of hands-on experience developing and testing coated touch screen glass for all sorts of uses (industrial kiosk applications, medical monitors, commercial display panels) at Saiweiglass. Here, by category, is everything we know about each of the three types of film coating – all the science, tested performance data, and key selection factors – so you can specify the right glass surface treatment for your first order.
What Are AG, AR, and AF Coatings? A Quick Overview

AG, AR and AF all are three specific types of coating currently applied to display glass and touch screen glass covers. They are all designed to change the interaction of light with the glass, but each caters to a very different optical issue. Here is a chart comparing anti-glare vs anti-reflective vs anti-fingerprint coating technology.
| Property | AG (Anti-Glare) | AR (Anti-Reflective) | AF (Anti-Fingerprint) |
|---|---|---|---|
| Full Name | Anti-Glare Coating | Anti-Reflective Coating | Anti-Fingerprint Coating |
| Mechanism | Diffuse reflection via surface roughness | Thin-film destructive interference | Low surface energy oleophobic layer |
| Primary Benefit | Eliminates harsh glare under strong light | Maximizes light transmission and clarity | Resists fingerprint and oil smudges |
| Typical Transmittance | 82%–93% | 95%–99%+ | 92%–95% (minimal impact) |
| Process | Chemical etching or spraying | Vacuum deposition (optical coating) | Nano-coating dip or spray |
| Best For | Outdoor displays, advertising screens | Medical monitors, precision displays | Public touchscreens, kiosks, POS |
AG scatters light AR cancels reflected light AF repels oils They address different issues and cannot be used instead of each other – the choice of the most appropriate agent depends on what environment your application system operates in and how the user will interact with it.
How AG (Anti-Glare) Coating Works — Mechanism and Performance

AG coating changes the normally mirror-like glare producing glass surface into a non-glare, diffuse-reflection surface through scattering the light rather than reflecting it. What separates anti-glare glass from a piece of ordinary glass is that a typical reflective surface will evenly reflect the light “mirror-like” reflection of the predominantly overhead light sources or windows, while the AG glass ‘diffuses” the reflection of the light so it is no longer so enervating to the image that is being displayed
The Chemical Etching Process
AG is formed by chemical etch or spray which produces microscopic surface roughness on the glass. During etching, an acid solution (typically hydrofluoric acid based chemicals) etchants which have an uneven surface to the glass, resulting in a plane texture of peaks and troughs to a micrometer level of precision. Because of this roughness of the glass, when light rays strike the surface they are reflected in many directions rather than all being reflected coherently toward the observer.
The Haze-Clarity Trade-Off
Haze is measured to the tests specified in ASTM D1003 whereby it is expressed as the percentage of transmitted light that deviates from the incident beam greater than 2.5. Higher haze percentages mean stronger the effect of glare reduction but at the expense of the image focus and sharpness. A display screen with 25% haze will scatter much of any ambient reflections but the text and graphics underneath will seem a little less sharp than without AG.
For touch screen use, most producers define a good practical AG glass to be within the 10%-25% haze range. A haze of less than 10% is of so little anti-glare benefit as to be nearly not worth the increased cost; a haze of more than 40% detracts from the resolution of the display underneath.
A lot of buyers also think that AG glass will make my screen look blurry. This is just a nightmare for all of us when the haze is too high for the application. Here is where you should specify the haze level— generally 10%-25% for indoor touch panels and 25%-40% for outdoor display units exposed to strong light.
How AR (Anti-Reflective) Coating Works — Mechanism and Performance

AR coating- The reflectivity of the glass is significantly decreased by coating the glass surface with a layer of optical coating materials. These are optical thin layers of materials such as MgF 2 , SiO 2 or TiO 2 vacuum deposited onto the glass. Since AR coating employs destructive interference in the thin film, no roughing of the reflector surface takes place as in AG treatment.
Thin-Film Interference: The Science
According to Georgia State University’s HyperPhysics reference, “each AR layer is made so that the reflected light from the top surface of the coating directly interferes destructively with the reflection from the coating/substrate interface”. When the layer thickness is one quarter of the desired wavelength a lag of 180 degrees exists at each interface, causing the two reflected beams to cancelling each other out. Multi-layer AR stacks produces this cancellation over a wider region of the spectrum – today’s broadband AR coatings are effective through the whole visible spectrum, from 380 to 780 nm.
A small piece of (ordinary) glass, with a refractive index of ~1.52, reflects ~4.26% of the incident light back per air-glass surface, or about 8.52% through both sides of the glass. (According to Edmund Optics, multiple-layer AR coatings bring the combined reflectance of both sides of the glass down to less than 0.5%, transmitting >99% of visible light.) This explains why the images through the AR glass are higher-contrast and sharper than those presented through uncoated or AG-treated glass.
The manufacturing process for the AR glass requires vacuum deposited coating tools – either PVD or sputter coating. As opposed to AG treatment, this is a heavy investment cost of AR coating.
Up to 50% reduction in reflectionmeans virtually no degradation of display quality. In addition good AR coatingwill perform as good as no coating ‘ s on other display surfaces. So it is ideal for any display or display panel for example medical display, high resolution industrial display, e-books.
How AF (Anti-Fingerprint) Coating Works — Mechanism and Performance

AF coating tackles a issue that neither AG nor AR can. This is the build-up of fingerprint residues, oil smudges and other dirt particles that accumulated on touch screen surfaces. An anti-fingerprint coating is a nanometer-thin film of fluorinated polymer or fluorosilane chemical that significantly reduces the glass’s surface energy so that water and oil lies in droplets rather than spreads.
The Lotus Effect Principle
AF coating technology is influenced by the lotus leaf—an aspect of nature that acts as a superhydrophobic surface, repelling water and other contamination by low surface energy and micro/nanostructuration. For glass applications the AF coating is applied to the surface of the glass as a dense film of 50-200 nanometers. This leads to a decreased the surface energy of the glass from ca 72 mN/m (ordinary glass surface) to 15-20 mN/m (per research published in Surface Engineering, Taylor & Francis, 2022).
Durability and Wear
The AF coating is the most abrasive of the three treatments. As it resides on the outside surface of glass, and is only nanometers thick, it slowly wears away at the surface surface to daily touch controls. Under normal conditions of use, the AF coating should last 6-12 months before the degradation becomes visually noticeable.
Industrial panel touchscreens in very high-traffic situations (kiosk terminals, pos systems, etc.) will degrade more quickly and will require recoating at regular intervals.
The thinking that AF coating ‘makes the surface self-cleaning’ is sadly incorrect. It only makes fingerprints etc easier to clean and less visible, but will not stop them forming in the first place. applications which require a truly clean surface (medical devices, cleanroom displays, etc.) will still require the existing cleaning regimes now used.
AG vs AR vs AF Coating: Side-by-Side Performance Comparison

Now that the various mechanisms are understood, the true challenge for engineers and purchasing teams is how does each of the three coating types compare against each other across the measure that are most important in selecting a touch screen glass. Presented below is a master comparison chart, which brings together the major performance measures based on industry specs and testing.
| Dimension | AG (Anti-Glare) | AR (Anti-Reflective) | AF (Anti-Fingerprint) |
|---|---|---|---|
| Light Transmittance | 82%–93% | 95%–99%+ | 92%–95% |
| Surface Reflectance | Diffused (scattered) | <0.5% (eliminated) | Unchanged (~4% per surface) |
| Haze Value | 1%–70% (adjustable) | ~0% (no haze) | ~0% (no haze) |
| Image Clarity | Reduced (matte effect) | Maximum (no distortion) | Maintained |
| Fingerprint Resistance | Low | Low | High (oleophobic) |
| Outdoor Readability | Good (scatters glare) | Excellent (high contrast) | No improvement |
| Coating Durability | Permanent (etched into glass) | Long-lasting (hard coating) | 6–12 months (wears off) |
| Relative Cost | $ | $$$ | $$ |
| Cleaning Ease | Moderate (textured surface) | Low (shows fingerprints) | Excellent (wipes clean) |
The biggest specs mistake we see in our experience making coated glass for touch screen applications is looking at the coatings as quality tiers – “AR is a step up from AG” or “AF is an upgrade over AR.” That’s not the case. Each type of coating brings a specific optical usability solution to the table. If you have a medical screen that requires the highest image fidelity, adding an AG coating isn’t going to make it any better.
Or a screen in outdoor advertising, you can’t use just AR to take glare off the strong sunlight.
AR for optical clarity,AG for reduction of glare in a very bright environment and AF for comfort of interaction with the screen by the user. Your coating choice depends on the environment and how the users interact with the screen- not on which one is ‘best’.
How to Choose the Right Coating for Your Application

Choosing the appropriate glass coating begins with these three questions: where will the display be installed, who will be touching it, and what does the display need to communicate?
Based on our supply of touch screen glass to OEM clients for industrial, medical, and commercial uses, we know that selection of coating can eradicate the majority of complaints after installation.
Application-Based Decision Matrix
| Application | Recommended Coating | Why |
|---|---|---|
| Outdoor display / Digital signage | AG or AG+AR | Direct sunlight creates intense glare; AG scatters it effectively |
| Medical monitor / Diagnostic display | AR or AR+AF | Image accuracy is critical; AR preserves full optical clarity |
| Public kiosk / ATM / POS terminal | AF or AG+AF | High-traffic touch = constant fingerprint accumulation |
| Industrial touchscreen / HMI panel | AG+AF | Factory lighting causes glare; gloved/oily hands leave marks |
| E-book reader / Tablet display | AG (low haze) or AR | Readability in varied lighting; text clarity matters |
| Automotive / In-vehicle display | AR+AF | Reduce light reflection from windshield; easy cleaning |
Selection Checklist
- ✔
Environment: Is the display used indoors, outdoors, or semi-outdoor? Strong ambient light favors AG; controlled indoor lighting favors AR. - ✔
Touch frequency: Will multiple users interact with the screen daily? High-traffic touch panels need AF coating as a baseline. - ✔
Image quality requirement: Does the application demand pixel-level accuracy (medical imaging, CAD)? AR is the only coating that maintains maximum display resolution. - ✔
Budget constraints: AG treatments cost 30%–50% less than AR coatings. For volume applications where moderate clarity trade-offs are acceptable, AG delivers the best cost-performance ratio. - ✔
Maintenance capacity: AF coating wears off in 6–12 months. If periodic recoating is impractical, consider AG as a permanent, maintenance-free alternative for glare control.
Begin with your environment (indoor or outdoor), then touch frequency, and finally think about what your image quality requirements are. Most industrial touchscreens require dual coat combinations instead of a single coating.
Can You Combine AG, AR, and AF Coatings?

Yes—and in numerous instances, layering coating types produced improved effects than individual coatings. Advanced glass production techniques provides several attributes, such as multiple layer coating stacks, where each coating layer performs a different function. One primary restriction is coating compatibility: not all combinations are the same, and the order of stacking is significant.
| Combination | Benefits | Best Use Case | Cost Impact |
|---|---|---|---|
| AG + AF | Glare reduction + smudge resistance | Outdoor kiosks, industrial HMI panels | +30%–40% over AG alone |
| AR + AF | Maximum clarity + fingerprint resistance | Medical displays, consumer electronics, automotive | +20%–30% over AR alone |
| AG + AR | Reduced glare + reduced reflection for outdoor clarity | Outdoor digital signage, semi-outdoor displays | +50%–70% over AG alone |
| AG + AR + AF | Full spectrum: anti-glare + anti-reflective + anti-fingerprint | Flagship devices, demanding industrial touchscreen environments | Highest cost tier |
The most common industrial coating combination is AR + AF. In most internal applications, anti-reflective glass with an anti-fingerprint coating hits two foremost customer concerns: optical transparency and convenient cleanability. When outdoor applications receive direct sunlight, anti-glare plus anti-fingerprint appears to be the most practical solution.
When application cost is not an issue and peak optical transmission is desired, the full three-layer composite of AG + AR + AF is the highest American Made approach. A very complex coating technology process is necessary, and the processing cost is extremely high. In practice, the three stack approach represents the largest portion of custom glass orders in medical, military, and high-end automotive markets.
Combining coatings has the advantage of addressing multiple issues simultaneously. Aggressively is the most popular industrial combination. Outdoor environments call for AG + AF. Only in extraordinary circumstances is the full AG + AR + AF composite recommended. In the applications we have seen so far, this is the coating combination selected for all custom orders of medical, military and high-end automotive glass.
About This Comparison
Most applications can benefit from adding multiple coatings to the glass surface. AR + AF is the most prevalent combination. AG + AF is more suitable for outdoor touchscreens or high touch environments. AG + AR + AF stacks are unique to applications where performance criteria outweigh costs.
Frequently Asked Questions
Q: What is AF glass?
View Answer
Q: What is the difference between AG, AR, and AF coating?
View Answer
Q: Does AG glass make the screen look blurry?
View Answer
Q: How long does the AF coating last?
View Answer
Q: What is AR coating on screen protectors?
View Answer
Q: How do you ensure coating uniformity across large displays?
View Answer
Need Custom Coated Touch Screen Glass?
Saiweiglass can provide you with AG, AR, AF, or a combination of coatings for all the industrial, medical, and commercial touch screen applications. Give us your definitions and requirements and we recommend the best coating for you.
References & Sources
- ASTM D1003-21: Standard Test Method for Haze and Luminous Transmittance of Transparent Plastics — ASTM International
- Anti-Reflection Coatings — HyperPhysics — Georgia State University, Department of Physics and Astronomy
- Anti-Reflection (AR) Coatings — Edmund Optics Knowledge Center
- Surface Engineering for Anti-Fingerprint Applications (2022) — Taylor & Francis, Surface Engineering Journal
- Anti-reflective Coating — Wikipedia
- Anti-Reflection Coatings — PVEducation.org
- Anti-Reflective Coatings Market Size, Growth and Forecast to 2033 — Straits Research









