Touch Sensors

Part Number	Description / PDF	Quantity
FSR01CE Ohmite	FORCE SENSING RESISTOR	354
NNAMC1580PC01 Neonode	INFRARED TOUCH SENSOR 0 DEGREES	150
W7ED-12L Omron Electronics Components	TOUCH SENSOR	52
W7ED-12F Omron Electronics Components	TOUCH SENSOR	0
FSR06CE Ohmite	FORCE SENSING RESISTOR	72
34-00004 Interlink Electronics	SENSOR FORCE RES 0.04-4.5LBS	2391
30-61710 Interlink Electronics	SENSOR FORCE RES 0.04-4.5LBS	717
W7ED-11F Omron Electronics Components	TOUCH SENSOR	117
NNAMC2300PC01 Neonode	INFRARED TOUCH SENSOR 0 DEGREES	66
34-00065 Interlink Electronics	SENSOR FORCE RES 0.04-4.5LBS	396
NNAMC1800PC01 Neonode	INFRARED TOUCH SENSOR 0 DEGREES	132
KT5151 ifm Efector	CAPACITIVE ILLUMINATED PUSHBUTTO	0
SEN0298 DFRobot	RP-C7.6-LT THIN FILM PRESSURE SE	35
SEN0299 DFRobot	RP-L-400 THIN FILM PRESSURE SENS	12
NN AMC 1150 PC01 Neonode	INFRARED TOUCH SENSOR 0 DEGREES	120
NN AMC 1801 PC01 Neonode	INFRARED TOUCH SENSOR 90DEGREES	90
08430211103 Altech Corporation	TOUCH SENSOR M10 P10DB-10	0
SEN0296 DFRobot	RP-S40-ST THIN FILM PRESSURE SEN	85
NN AMC 3100 PC01 Neonode	INFRARED TOUCH SENSOR 0 DEGREES	218
NN AMC 3101 PC01 Neonode	INFRARED TOUCH SENSOR 90DEGREES	97

Touch Sensors

1. Overview

Touch sensors are input devices that detect and record physical contact or proximity through electrical, optical, or mechanical signals. They convert tactile interactions into digital data, enabling human-machine interfaces (HMIs) in modern electronics. Their significance spans consumer electronics, industrial automation, automotive systems, and medical devices, driving innovations in user experience and system responsiveness.

2. Main Types and Functional Classification

Type	Functional Characteristics	Application Examples
Capacitive Touch	Measures changes in capacitance when a conductive object approaches	Smartphones, tablets, touchpads
Resistive Touch	Registers pressure through contact between resistive layers	ATMs, industrial control panels
Surface Acoustic Wave (SAW)	Uses ultrasonic waves disrupted by touch contact	Public kiosks, medical displays
Infrared Touch	Grid of IR LEDs and photodetectors interrupted by touch	Digital signage, large-format displays
Optical Imaging	Camera-based detection of touch-induced light changes	Interactive whiteboards, gaming consoles

3. Structure and Components

Typical touch sensors consist of: - Sensing Layer: Conductive materials (e.g., ITO for capacitive) arranged in electrode grids - Substrate: Glass or polymer base providing mechanical support - Sensor Array: Matrix of individual sensing elements (pixels) - Controller IC: Converts analog signals to digital coordinates - Protective Coating: Scratch-resistant layer (e.g., Gorilla Glass) Flexible sensors use printed electronics on polymer films for bendable applications.

4. Key Technical Specifications

Parameter	Description	Importance
Sensitivity	Minimum detectable touch force (0.1-5N)	Determines usability in precision applications
Resolution	Position accuracy (0.1-2mm)	Affects interface responsiveness
Response Time	Signal processing latency (1-10ms)	Critical for real-time control systems
Transparency	Light transmission rate (85-98%)	Essential for display integration
Environmental Tolerance	Operating temperature (-20 C to 85 C), humidity resistance	Dictates deployment conditions

5. Application Fields

Consumer Electronics: Smartphones (capacitive), gaming controllers (force sensors)
Industrial: HMI panels (resistive), robotic touch feedback systems
Automotive: Infotainment systems (projected capacitive), steering wheel controls
Medical: Sterilizable touch interfaces (SAW), patient monitoring devices
Commercial: Interactive retail displays (infrared), POS terminals

6. Leading Manufacturers and Products

Manufacturer	Representative Product	Key Features
Synaptics	ClearPad S Series	Capacitive sensing with wet finger tracking
Microchip Technology	maXTouch T	Low-power capacitive controllers
STMicroelectronics	STMPE Series	Resistive/capacitive hybrid solutions
Tyco Electronics	Capacitive Touch Sensors	Automotive-grade durability
Elo Touch Solutions	ProTouch 5823MT	SAW technology for 20-point multitouch

7. Selection Recommendations

Key considerations: - Application Type: Capacitive for consumer devices, resistive for industrial environments - Environmental Conditions: SAW for dusty environments, infrared for large surfaces - Cost Constraints: Resistive solutions offer lower BOM costs - Accuracy Requirements: Optical for sub-millimeter precision - Power Budget: Capacitive sensors typically consume less standby power

Industry Development Trends

Future directions include: - Flexible Sensors: Graphene-based materials enabling foldable displays (e.g., Samsung Galaxy Z Fold) - 3D Touch: Force-sensitive layers for pressure-aware interfaces - Transparent Electronics: Metal mesh technologies achieving >95% transparency - AI Integration: Machine learning algorithms for gesture recognition (Apple ProMotion) - Energy Harvesting: Self-powered sensors using piezoelectric effects Market growth projected at 12.3% CAGR through 2030, driven by automotive HMI and IoT applications.