SCLSA29B
October 2024 – May 2025
SN74LVC1G16
PRODUCTION DATA
1
1
Features
2
Applications
3
Description
4
Pin Configuration and Functions
5
Specifications
5.1
Absolute Maximum Ratings
5.2
ESD Ratings
5.3
Recommended Operating Conditions
5.4
Thermal Information
5.5
Electrical Characteristics
5.6
Switching Characteristics
5.7
Typical Characteristics
6
Parameter Measurement Information
7
Overview
8
Functional Block Diagram
9
Detailed Description
9.1
Feature Description
9.1.1
Open-Drain CMOS Outputs
9.1.2
CMOS Schmitt-Trigger Inputs
9.1.3
Clamp Diode Structure
10
Application and Implementation
10.1
Application Information
10.2
Typical Application
10.2.1
Design Requirements
10.2.1.1
Power Considerations
10.2.1.2
Input Considerations
10.2.1.3
Output Considerations
10.2.2
Detailed Design Procedure
10.3
Application Curves
10.4
Power Supply Recommendations
10.5
Layout
10.5.1
Layout Guidelines
10.5.2
Layout Example
11
Device and Documentation Support
11.1
Documentation Support
11.1.1
Related Documentation
11.2
Receiving Notification of Documentation Updates
11.3
Support Resources
11.4
Trademarks
11.5
Electrostatic Discharge Caution
11.6
Glossary
12
Revision History
13
Mechanical, Packaging, and Orderable Information
10.5.1
Layout Guidelines
Bypass capacitor placement
Place near the positive supply terminal of the device
Provide an electrically short ground return path
Use wide traces to minimize impedance
Keep the device, capacitors, and traces on the same side of the board whenever possible
Signal trace geometry
8mil to 12mil trace width
Lengths less than 12cm to minimize transmission line effects
Avoid 90° corners for signal traces
Use an unbroken ground plane below signal traces
Flood fill areas around signal traces with ground
Parallel traces must be separated by at least 3x dielectric thickness
For traces longer than 12cm
Use impedance controlled traces
Source-terminate using a series damping resistor near the output
Avoid branches; buffer each signal that must branch separately