Recent Updates:

October 2019 Updates

Modified: 31 October, 2019

Blog updates during October 2019.

Jupyter

Modified: 28 October, 2019

A tutorial on Jupyter Notebooks and Jupyter Labs.

Rotation Matrices

Modified: 26 October, 2019

An introduction to rotation matrices. What they are, how to calculate them, and what they are useful for!

Quaternions

Modified: 14 October, 2019

A tutorial on quaternions, including calculators to convert between quaternions, rotation matrices and axis-angle notations.

Visual Studio Code

Modified: 11 October, 2019

Shortcuts, key bindings, compiling C/C++ and more info about the Visual Studio Code IDE.

CIRCUIT DESIGN

Inrush Current

Date Published:	January 13, 2015
Last Modified:	January 13, 2015

Overview

Power supplies are responsible for a large number of inrush current issues due to their large amounts of input and output capacitance. Advanced switch-mode power supplies will limit the inrush current to the output appropriately (either fixed or set by a resistor to a dedicated pin on the SMPS controller), but you still have the input capacitance to deal with.

Standard Resistors

Standard resistors are one of the simplest ways of limiting inrush current. They are typically used in low-power situations, as unlike many of the more complex inrush current protection methods, their resistance does not reduce after start-up, meaning they dissipate significant power continuously and can cause large voltage drops.

NTC Thermistors

NTC thermistors can be used for reducing the amount of inrush current.

A graph showing the effect of a NTC thermistor limiting the inrush current to a circuit.

They will always be some measurable amount of voltage drop when using a NTC, as some continuous thermal dissipation is required to keep the thermistor warm enough to be in it’s low resistance state.

The total energy $ E $ provided by the inrush current is given by:

$$ E = \frac{1}{2} C V_{in}^2 $$

where:
$C$ = the downstream capacitance, in Farads
$V_{in}$ = the input voltage, in Volts

Note

You may be initially confused, thinking, wait, this is the equation for the energy stored in the capacitor, not the energy dissipated by the thermistor. The cool thing is, in this circuit, the energy stored in the capacitor and the energy dissipated by the thermistor (or any resistor) is exactly the same!

Note

The minimum resistance (provided by the NTC thermistor), (R_{min}), is given by:

$$ R_{min} = \frac{V_{in}}{I_{max}} $$

where:
$I_{max}$ = the desired maximum inrush current, in Amps

This assumes that the other resistances in the path of the inrush current (e.g. the trace resistance, the ESR of the input capacitors) is negligible.

The steady-state current must not be larger than the maximum steady-state current rating of the NTC thermistor

The steady-state current rating of the NTC thermistor must be derated if the ambient temperature is too high.

If steady-state power dissipation or voltage drop is a big issue, the NTC thermistor can bypassed with a timed relay during steady-state operation.

Ametherm is a popular manufacturer of NTC themristors. As of Jan 2015, they have the following material types: A, B, C, G, H, I, L, M, N, Q, R, S. There provide an online calculator (http://www.ametherm.com/inrush-current/) to quickly choose a NTC thermistor for limiting the inrush current to a power supply.

Like this page? Upvote with shurikens!