The thermal resistance (θJA) of the R6576ENZ4C13 is typically around 30°C/W, but it can vary depending on the PCB layout, copper area, and airflow. It's essential to consider thermal design and heat dissipation in your application.
To ensure stability, follow the recommended capacitor values and types in the datasheet. Use a 10uF or larger ceramic capacitor for CIN and a 22uF or larger ceramic capacitor for COUT. Additionally, keep the capacitor leads short and use a low-ESR capacitor to minimize oscillation risk.
Although the datasheet specifies a maximum input voltage of 18V, it's recommended to limit the input voltage to 15V or less to ensure reliable operation and prevent damage to the internal circuitry.
The R6576ENZ4C13 is rated for operation up to 125°C, but its performance and reliability may degrade at higher temperatures. Be sure to consider the operating temperature range and potential thermal issues in your design.
To calculate power dissipation, use the formula: Pd = (VIN - VOUT) x IOUT. Consider the maximum input voltage, output voltage, and output current to determine the maximum power dissipation. Ensure that your design can handle the resulting heat generation.
Trust Checks
This model has been built in collaboration with the manufacturer.
Manufacturer Collaborated
This model has been verified by system checks.
System Verified
This model has been reviewed by community users.
Community Approved
Sponsored
R6576ENZ4C13 Overview
Use the download button to access the R6576ENZ4C13 schematic symbol, PCB footprint, and 3D model.
To find more CAD model downloads similar to this part, try a partial part number search, like R6576,
or try a keyword search, such as Power Field-Effect Transistors
