Qtenboard Infrared Touch Frames Explained

Infrared vs Capacitive Touch — Why Stability and Size Matter More Than Touch Point Numbers

In the interactive display industry, touch performance is often simplified into a single number: touch points.

20 points.
40 points.
50 points.
Even higher.

As a manufacturer, we understand why buyers chase higher numbers. But at Qtenboard, which designs, assembles, and tests interactive displays daily, we know a deeper truth:

Touch quality is defined by system stability, not by maximum touch points.

This article explains how infrared touch frames work, compares them with capacitive touch in a clear technical table, and — most importantly — explains Qtenboard’s customization capabilities and engineering-backed recommendations.

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Why Touch Technology Choice Matters

Touch is not an isolated component. It interacts with:

• Display size and resolution
• Glass thickness
• Frame flatness
• Controller algorithms
• User environment

A mismatch in any of these can lead to:

• Ghost touches
• Missed inputs
• Writing lag
• Long-term drift

Professional manufacturers evaluate touch as a system-level design decision, not as a single spec on a datasheet.

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1. What Is an Infrared Touch Frame?

An infrared (IR) touch frame creates a grid of invisible infrared beams across the display surface.

• IR emitters are placed along two sides of the frame
• IR receivers are placed on the opposite sides
• Together, they form an X–Y detection matrix

When an object blocks one or more beams, the controller calculates the precise touch coordinates.

Key Characteristics of Infrared Touch

• No physical pressure required
• No conductive material required
• Works with finger, glove, stylus, or pointer
• Independent from the LCD or glass layer

Infrared touch is especially suitable for large-format interactive displays, such as education boards, meeting rooms, and public collaboration spaces.

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2. Core Components of Infrared Touch Frames

2.1 Infrared Emitters & Receivers

• Wavelength: ~850–940 nm
• Industrial-grade LEDs ensure longevity and stable output
• LED spacing affects touch resolution and accuracy

2.2 Touch Controller & Algorithm

The controller processes:

• Interrupted beam patterns
• Signal noise filtering
• Multi-touch conflict resolution

A strong controller algorithm:

• Filters accidental palm touches
• Improves writing smoothness
• Reduces ghost points

📌 Two frames with the same “touch point count” can feel completely different due to algorithm quality.

2.3 Frame Structure & Assembly Precision

Infrared frames require:

• High flatness and structural stability
• Precise LED alignment
• Minimal mechanical tolerance

Poor assembly causes:

• Dead zones
• Inconsistent edge response
• Touch drift over time

Infrared frames are therefore mechanical and electronic precision components, not just electronics.

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3. Understanding Infrared Touch Points — More Is Not Always Better

Touch points indicate the maximum simultaneous inputs a display can recognize.

Typical ranges:

• 20 points: standard multi-user interaction
• 30–40 points: education and collaboration
• 50 points: multi-user group interaction
• 60+ points: custom, factory-configured solutions

Why Higher Point Counts Can Reduce Performance

1. Signal Overlap: denser IR beams can interfere
2. Controller Load: more points require faster processing
3. False Touches: more beams increase chance of accidental activation
4. Marginal Real-World Benefit: most classrooms/meeting rooms rarely exceed 15 simultaneous touches

Qtenboard Insight: A well-tuned 20–50 point IR frame often outperforms an unstable 60+ point system in reliability and user experience.

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4. Infrared vs Capacitive Touch — Factory-Level Comparison

Omadus	Infrared (IR)	Capacitive (PCAP)
Touch Principle	Infrared beam interruption	Electrical capacitance change
Medium Supported	Finger, glove, stylus, pointer	Finger or conductive stylus
Large Size Scalability	Excellent (65”–110”+)	Limited beyond large sizes
Accuracy	High (algorithm dependent)	Very high
Writing Smoothness	Very good	Excellent
Ambient Light Sensitivity	Moderate	Low
Dust / Debris Impact	Requires periodic cleaning	Minimal
Glass Thickness Impact	Puudub	Significant
Cost for Large Panels	Lower	Much higher
Maintenance & Repair	Replaceable frame	Full glass replacement
Typical Use Cases	Education, meetings, collaboration	Design, precision input

📌 Key takeaway: Capacitive touch is better for small, precision-oriented panels, while infrared is scalable, flexible, and cost-efficient for large interactive displays.

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5. Matching Touch Technology to Display Size

At Qtenboard, we guide OEMs based on screen size:

Display Size	Recommended Technology	Reasoning
≤55 inches	Capacitive (PCAP)	Smaller screens benefit from high precision, smooth strokes, and premium feel
≥55 inches	Infrared (IR)	Large displays require scalable, cost-effective touch, compatible with gloves, stylus, or multiple users

Why This Matters

• Infrared is ideal for 65”–110” panels: multi-user, cost-effective, easy maintenance
• Capacitive is ideal for smaller panels: high precision, smooth handwriting
• Qtenboard supports custom IR frames with higher points (60–80) for special projects, yet we recommend 20–50 points for stability and reliability

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6. Qtenboard Customization & Factory Capabilities

As a direct manufacturer, Qtenboard offers:

• Custom infrared touch point counts (20–80 points)
• Frames optimized for large-format displays
• Tailored LED spacing and scanning frequency
• Integration with varying glass thicknesses and OPS modules
• Algorithm optimization for palm rejection and smooth writing

Engineering-First Recommendations

• 20–50 points for standard large panels
• Avoid over-dense beams that reduce accuracy
• Matching touch technology to size and usage scenario improves reliability

📌 This approach ensures OEMs get both flexibility and long-term stability.

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7. Writing & Interaction Experience

Infrared Touch

• Stable and responsive
• Slightly softer stroke edges
• Excellent for multi-user collaboration
• Works consistently across large panels

Capacitive Touch

• Extremely smooth handwriting
• Strong palm rejection
• Best for precision input on small panels

Takeaway: Infrared excels in education, meetings, and collaboration where reliability and multi-user capability outweigh micro-level smoothness.

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8. Environmental Adaptability

Infrared Touch:

• Works with gloves and stylus
• Handles high user variability
• Requires simple cleaning

Capacitive Touch:

• Sensitive to moisture
• Limited stylus options
• Higher repair cost

Infrared is generally more tolerant in public, education, and enterprise environments.

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FAQ – Infrared Touch & Qtenboard Customization

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Final Thoughts: A Factory’s Perspective

At Qtenboard, we don’t sell numbers — we engineer systems.

Touch technology is not about chasing the highest touch points, but about delivering:

• Stability
• Skaalatavus
• Cost-effectiveness
• Long-term usability

By combining:

• Size-based touch selection (infrared ≥55”, capacitive ≤55”)
• Customizable infrared points (20–80)
• Optimized frame assembly and algorithm tuning

We provide OEMs and ODM partners with solutions that are reliable, flexible, and ready for real-world deployment.