Configurable Switch Components

Configurable Switch Components - Lens

Image	Part Number	Description / PDF	Quantity	Rfq
	5.49275.0820411 RAFI	LENS RF15	0
	0854.0581 Schurter	LENS CLEAR EMF/AF/SBE 18X24MM	0
	5.46681.0211607 RAFI	KEYCAP RK90 1-MOD.	0
	0854.0605 Schurter	LENS CLEAR BLUE EMF 18X18MM	0
	0854.0611 Schurter	LENS PEARL EMF 18X18MM	0
	0854.0592 Schurter	CONFIG SWITCH LENS RED RECT	0
	5.49273.0430411 RAFI	LENS RF 15	0
	61-9231.5 EAO	ACCY LENS GRN TRANSLUC 15.3X21.5	0
	02-902.5 EAO	LENS GREEN FLAT 17.6X25.6 PLASTI	0
	5.49079.0121700 RAFI	LENS	0
	5.49227.0101002 RAFI	LENS	0
	5.46681.0020409 RAFI	CONFIG SWITCH LENS YELLOW RECT	0
	5.49263.0161306 RAFI	LENS	0
	0854.0612 Schurter	CONFIG SWITCH LENS RED SQUARE	0
	0854.0623 Schurter	CONFIG SWITCH LENS GREEN ROUND	0
	5.49205.0080214 RAFI	LENS OPAK BK	0
	5.49077.0031002 RAFI	LENS 1-MOD. TRANSP. COLOURLESS	0
	5.49273.0430319 RAFI	LENS RF 15	0
	5.49259.0131502 RAFI	LUMOTAST 75 IP65 LENS ROUND TRAN	0
	5.49273.0111002 RAFI	LENS TRANSP. COLOURLESS	0

Configurable Switch Components - Lens

1. Overview

Configurable Switch Components - Lens refers to a category of modular electro-optical switching devices that integrate adjustable optical lens systems with customizable switching mechanisms. These components enable precise control of electrical circuits through optical signal modulation, combining mechanical actuation with light-based sensing technologies. Their importance in modern systems lies in enabling adaptive automation, high-precision detection, and non-contact operation across industrial, medical, and consumer electronics applications.

2. Major Types and Functional Classification

Type	Functional Characteristics	Application Examples
Adjustable Focus Lens Switches	Variable focal length control with position feedback	Machine vision systems, robotic alignment
Multi-Spectrum Optical Switches	Dual-band IR/visible light operation	Security sensors, optical communication
Programmable Matrix Switches	Software-defined optical path routing	Telecom networks, lab-on-chip devices
Environmental Resilient Units	IP69K rated for harsh conditions	Outdoor automation, industrial IoT

3. Structural and Technical Composition

Typical construction includes: - Lens Assembly: Graded-index (GRIN) or aspheric lenses with anti-reflective coating - Actuation Mechanism: Piezoelectric, electromagnetic, or MEMS-based micro-actuators - Signal Interface: Standardized PCB mounting with configurable pinouts - Housing: Aluminum alloy or polycarbonate enclosures with thermal compensation - Control Circuitry: Integrated microcontrollers for parameter configuration

4. Key Technical Specifications

Parameter	Typical Range	Importance
Wavelength Range	400-1600nm	Determines optical compatibility
Switching Speed	0.1-50ms	Impacts real-time performance
Resolution	1-10 m	Critical for precision applications
Operating Temperature	-40 C to +125 C	Defines environmental suitability
MTBF	100,000 - 1,000,000 hours	Measures long-term reliability

5. Application Fields

Industrial Automation: Conveyor sorting systems, CNC machine tools
Medical Equipment: Non-contact surgical instrument controllers
Telecommunications: Optical cross-connect systems
Consumer Electronics: Smart home sensors, AR/VR headsets

6. Leading Manufacturers and Products

Manufacturer	Representative Product	Key Features
TE Connectivity	LensSwitch 7000	IP67 rating, 0.5ms response time
Omron Corporation	ZW-F3 Series	Dual-beam stabilization, 50m detection range
Honeywell	FS-Lens Pro	AI-driven adaptive focusing
Hamamatsu Photonics	C12880MA	Multispectral imaging integration

7. Selection Recommendations

Key considerations: - Environmental factors (temperature, vibration, contamination) - Optical requirements (wavelength sensitivity, light intensity) - Integration constraints (form factor, mounting options) - Control interface compatibility (analog/digital protocols) - Cost vs. performance trade-offs (Example: Semiconductor manufacturing requires Class 10 resolution)

8. Industry Trends Analysis

Emerging developments include: - Integration with edge AI for self-optimizing systems - Miniaturization through MOEMS (Micro-Opto-Electro-Mechanical Systems) - Adoption of plastic photonics for cost reduction - Increased use in autonomous vehicle LiDAR systems - Development of self-cleaning lens coatings using nanotechnology