Manufacturer Part Number
MAX313EUE+T
Manufacturer
analog-devices
Introduction
The MAX313EUE+T is a highly reliable SPST analog switch, suitable for various applications requiring efficient multiplexing and demultiplexing.
Product Features and Performance
Single SPST NO switch configuration
4 independent circuits
Offers low on-state resistance of 10Ohm
Channel-to-Channel matching of 300mOhm
Quick switch time of 225ns for turn-on and 185ns for turn-off
Minimal charge injection of 20pC
Low channel capacitance of 15pF
Exceptionally low leakage current of 500pA max
Excellent crosstalk performance of -85dB @ 1MHz
Product Advantages
High precision and reliability
Low on-state resistance enhances performance
Fast switching speeds improve responsiveness
Minimal charge injection and leakage current ensure signal integrity
Robust crosstalk resistance enhances multi-channel operation
Key Technical Parameters
On-State Resistance (Max): 10Ohm
Channel-to-Channel Matching (ΔRon): 300mOhm
Voltage Supply, Single (V+): 4.5V to 30V
Voltage Supply, Dual (V±): ±4.5V to 20V
Switch Time (Ton, Toff) (Max): 225ns, 185ns
Channel Capacitance: 15pF
Leakage Current (Max): 500pA
Operating Temperature: -40°C to 85°C
Quality and Safety Features
Rigorous quality assurance processes
Safe operating temperature range from -40°C to 85°C
Built with high-quality materials to ensure durability and reliability
Compatibility
Compatible with surface mount technology
Mounting Type: Surface Mount
Package / Case: 16-TSSOP
Application Areas
Telecommunications
Data acquisition systems
Test equipment
Audio and video switching
Product Lifecycle
Currently in active production
Not nearing discontinuation
Options available for replacements or upgrades
Several Key Reasons to Choose This Product
High degree of integration facilitating compact designs
Low power consumption suitable for battery-operated devices
Precision performance ensures accurate signal routing
Elastic supply voltage range supports various design requirements
Durable and reliable for long-term deployment in critical systems