Learn Know-how
Effective Use of Decoupling Capacitors, Summary
2019.02.07
Over three articles we have explained “Effective Use of Decoupling Capacitors”. These are extremely important points relating to the use of capacitors to deal with noise, and so are here summarized.
・Effective Use of Decoupling (Bypass) Capacitors Point 1
・Point 2: Reducing the capacitor ESL (equivalent series inductance)
・Other matters to be noted
Point 1: Use of Multiple Decoupling Capacitors
In decoupling using multiple capacitors, the effects are different when using several capacitors having the same electrostatic capacitance and when using capacitors with different capacitances in combination.
■When using multiple capacitors with the same capacitance value
The impedance is lowered over all frequency ranges; effective for reducing noise overall.
■When using multiple capacitors with different capacitance values
The impedance can be lowered at higher frequencies; effective for reducing high-frequency noise. However, antiresonance may occur depending on the frequency, and conversely, the impedance may rise and noise may grow worse, so care must be taken.
Point 2: Reducing the Capacitor ESL
If capacitances are the same, the lower the ESL, the higher the resonance frequency rises. Thus reducing the ESL can improve the high-frequency characteristic, and high-frequency noise can be reduced more effectively.
■Using a capacitor that has the same value but is smaller in size
The ESL depends on the structure of the terminal portions; basically, smaller-size capacitors have smaller terminals, and so the ESL is normally smaller. When noise must be reduced at higher frequencies, selecting smaller-size capacitors is one option. However, attention must be paid to the DC bias characteristic.
■Using a capacitor with a lowered ESL
Among multilayer ceramic capacitors, there are types the ESL of which is lowered through innovations in the shape and structure, such as LW reversed type capacitors and three-terminal capacitors.
Effective Use of Decoupling Capacitors: Other Matters to be Noted
■Ceramic capacitors with a high Q factor
When Q is high, the impedance becomes extremely low in a specific narrow band. When Q is low, the impedance does not fall in this extreme manner, but the impedance can be lowered over a broad band.
■Thermal relief and other PCB patterns
Thermal relief and other PCB patterns, which are used with the goal of improving heat dissipation characteristics, increase the inductance component of the pattern. The increase in the inductance component causes the resonance frequency to be shifted to the low-frequency side, and so in some cases the desired noise elimination effect is not obtained.
■Virtual capacitor mounting when studying countermeasures
When adding a small-value capacitor to deal with high-frequency noise, placement of the capacitor as close as possible to the place where actual correction is needed should be studied, based on the theory that low-capacitance capacitors should be located as close to the noise source as possible. If placement is different during studies and after correction, impedance may differ, and the characteristics expected from evaluations may not be attained.
■Capacitance change rate of capacitors
If the capacitance change rate of a capacitor used to deal with noise is high, there may be large fluctuations in the resonance frequency, so that fluctuations and variation may occur in the band to be attenuated, and it may be difficult to achieve the intended noise suppression. Noise countermeasures that require large attenuation in a narrow band require special attention.
■Temperature characteristics of capacitors
The characteristic of a capacitor changes with temperature, and so when it is obvious from the application that a capacitor will be exposed to high or low temperatures or to extreme temperature changes, a device with a good temperature characteristic should be used.
For further details on each of these subjects, the links can be used to refer to the original articles. From the next article we will discuss noise countermeasures using inductors.
【Download Documents】 Switching Power Supply Basic of EMC and Noise Countermeasures
This is a handbook on the basics of EMC (electromagnetic compatibility) and noise countermeasures for switching power supplies. Based on the understanding of the basics of noise, it explains the noise countermeasures using capacitors and inductors in switching power supplies.
Learn Know-how
Electrical Circuit Design
- Soldering Techniques and Solder Types
- Seven Tools for Soldering
- Seven Techniques for Printed Circuit Board Reworking
-
Basic Alternating Current (AC)
- AC Circuits: Alternating Current, Waveforms, and Formulas
- Complex Numbers in AC Circuit
- Electrical Reactance
- What is Impedance? AC Circuit Analysis and Design
- Impedance Measurement: How to Choose Methods and Improve Accuracy
- Impedance Matching: Why It Matters for Power Transfer and Signal Reflections
- Resonant Circuits: Resonant Frequency and Q Factor
- RLC Circuit: Series and Parallel, Applied circuits
- What is AC Power? Active Power, Reactive Power, Apparent Power
- Power Factor: Calculation and Efficiency Improvement
- What is PFC?
- Boundary Current Mode (BCM) PFC: Examples of Efficiency Improvement Using Diodes
- Continuous Current Mode (CCM) PFC: Examples of Efficiency Improvement Using Diode
- LED Illumination Circuits:Example of Efficiency Improvement and Noise Reduction Using MOSFETs
- PFC Circuits for Air Conditioners:Example of Efficiency Improvement Using MOSFETs and Diodes
-
Basic Direct Current (DC)
- Ohm’s Law: Voltage, Current, and Resistance
- Electric Current and Voltage in DC Circuits
- Kirchhoff’s Circuit Laws
- What Is Mesh Analysis (Mesh Current Method)?
- What Is Nodal Analysis (Nodal Voltage Analysis)?
- Thevenin’s Theorem: DC Circuit Analysis
- Norton’s Theorem: Equivalent Circuit Analysis
- What Is the Superposition Theorem?
- What Is the Δ–Y Transformation (Y–Δ Transformation)?
- Voltage Divider Circuit
- Current Divider and the Current Divider Rule
Thermal design
-
About Thermal Design
- Changes in Engineering Trends and Thermal Design
- A Mutual Understanding of Thermal Design
- Fundamentals of Thermal Resistance and Heat Dissipation: About Thermal Resistance
- Fundamentals of Thermal Resistance and Heat Dissipation: Heat Transmission and Heat Dissipation Paths
- Fundamentals of Thermal Resistance and Heat Dissipation : Thermal Resistance in Conduction
- Fundamentals of Thermal Resistance and Heat Dissipation : Thermal Resistance in Convection
- Fundamentals of Thermal Resistance and Heat Dissipation : Thermal Resistance in Emission
- Thermal Resistance Data: JEDEC Standards, Thermal Resistance Measurement Environments, and Circuit Boards
- Thermal Resistance Data: Actual Data Example
- Thermal Resistance Data: Definitions of Thermal Resistance, Thermal Characterization Parameters
- Thermal Resistance Data: θJA and ΨJT in Estimation of TJ: Part 1
- Thermal Resistance Data: θJA and ΨJT in Estimation of TJ: Part 2
- Surface Temperature Measurements: Methods for Fastening Thermocouples
- Surface Temperature Measurements: Thermocouple Mounting Position
- Surface Temperature Measurements: Treatment of Thermocouple Tips
- Surface Temperature Measurements: Influence of the Thermocouple
- Estimating TJ: Basic Calculation Equations
- Estimating TJ: Calculation Example Using θJA
- Estimating TJ: Calculation Example Using ΨJT
- Estimating TJ: Calculation Example Using Transient Thermal Resistance
- Estimation of Heat Dissipation Area in Surface Mounting and Points to be Noted
- Surface Temperature Measurements: Thermocouple Types
- Summary
- Collection of Important Points Relating to Thermal Design
Switching Noise
- Procedures in Noise Countermeasures
- What is EMC?
-
Dealing with Noise Using Capacitors
- Understanding the Frequency Characteristics of Capacitors, Relative to ESR and ESL
- Measures to Address Noise Using Capacitors
- Effective Use of Decoupling (Bypass) Capacitors Point 1
- Effective Use of Decoupling Capacitors Point 2
- Effective Use of Decoupling Capacitors, Other Matters to be Noted
- Effective Use of Decoupling Capacitors, Summary
-
Dealing with Noise Using Inductors
- Frequency-Impedance Characteristics of Inductors and Determination of Inductor’s Resonance Frequency
- Basic Characteristics of Ferrite Beads and Inductors and Noise Countermeasures Using Them
- Dealing with Noise Using Common Mode Filters
- Points to be Noted: Crosstalk and Noise from GND Lines
- Summary of Dealing with Noise Using Inductors
- Other Noise Countermeasures
- Basics of EMC – Summary
Simulation
- Thermal Simulation of PTC Heaters
- Thermal Simulation of Linear Regulators
-
Foundations of Electronic Circuit Simulation Introduction
- About SPICE
- SPICE Simulators and SPICE Models
- Types of SPICE simulation: DC Analysis, AC Analysis, Transient Analysis
- Types of SPICE simulation: Monte Carlo
- Convergence Properties and Stability of SPICE Simulations
- Types of SPICE Model
- SPICE Device Models: Diode Example–Part 1
- SPICE Device Models: Diode Example–Part 2
- SPICE Subcircuit Models: MOSFET Example―Part 1
- SPICE Subcircuit Models: MOSFET Example―Part 2
- SPICE Subcircuit Models: Models Using Mathematical Expressions
- About Thermal Models
- About Thermal Dynamic Model
- Summary
-
About the ROHM Solution Simulator
- How to Access the ROHM Solution Simulator
- Trying Out the ROHM Solution Simulator (1)
- Trying Out the ROHM Solution Simulator (2)
- Starting a Simulation Circuit in the ROHM Solution Simulator
- ROHM Solution Simulator Toolbar Functions and Basic Operations
- ROHM Solution Simulator: User Interface
- Execution of Simulations
- Method for Displaying Simulation Results
- Simulation Result Display Tool: Wavebox
- Simulation Results Display Tool: Waveform Viewer
- Customization of Simulations
- Exporting Circuit Data to PartQuest™ Explorer
- Purchasing Samples for Evaluation
- Optimization of PFC Circuits
- Optimization of Inverter Circuits
- About Thermal Simulations of DC-DC Converters
- Circuit-Theory-Based Design Simulation