DC-DC|Evaluation
Losses in Synchronous Rectifying Step-Down Converters
2018.08.09
Points of this article
・The loss in a synchronous rectifying step-down converter is the sum of the losses of the various components.
From here, we embark on a study of losses in synchronous rectifying step-down converters. We begin by identifying the places at which losses occur in a synchronous rectifying step-down converter. Then, we consider the losses at each point.
Sites of Losses in a Synchronous Rectifying Step-Down Converter
Below is shown a simplified circuit of a synchronous rectifying step-down converter, indicating places at which losses occur. Loss occurrence sites are indicated by abbreviated names, in red.
PONH is the conduction loss due to the ON-resistance when the high-side MOSFET is turned on.
PONL is the conduction loss due to the ON-resistance when the low-side MOSFET is turned on.
PSWH is the switching loss of the MOSFETs.
Pdead_time is the dead time loss. When the timing is such that there is an interval in which the high-side MOSFET and low-side MOSFET are both turned on simultaneously, VIN and GND are nearly in a short-circuited state, and an overcurrent, sometimes called a shoot-through current or the like, flows. In order to avoid this, nearly all controller ICs cause both the high-side and the low-side MOSFETs to be turned off for a very short interval when switching the two MOSFETs on and off. This is called the dead time. It is necessary to ensure safety, but results in a loss.
PIC is the power supply current for a power supply IC, in this case, the controller IC for the synchronous rectifying step-down converter with external power transistors. In essence, this is the current consumed by the IC itself, and is the self current consumption.
PGATE is the gate charge loss of the external MOSFET. As a rule, current does not flow in a MOSFET gate, but the charge to drive the gate capacitance is necessary, and this becomes a loss. Losses occur in both the high-side and the low-side MOSFETs.
PCOIL is the conduction loss due to the DC resistance (DCR) of the output inductor.
The result of adding all of these losses is the loss of the synchronous rectifying step-down converter.
Total loss P=PONH+PONL+PSWH+Pdead_time+PIC+PGATE+PCOIL
PONH:Conduction losses due to ON-resistance of the high-side MOSFET while on
PONL:Conduction losses due to ON-resistance of the low-side MOSFET while on
PSWH:Switching losses
Pdead_time:Dead time losses
PIC:IC self current consumption loss
PGATE:Gate charge losses
PCOIL: Conduction losses due to the inductor DCR
From the next section, we will study individual losses.
【Download Documents】 Step-Down DC-DC Converter Examination of Losses
A hand book to study losses of synchronous rectifying step-down converters showing definitions of losses, relations to heat generation, loss equations for places at which losses occur in a circuit, examples of thermal calculation, relations to applications and Losses, and so on.
DC-DC
Basic
- Operation During Shutdown of a Boost DC-DC Converter
- Linear Regulator Basics
-
Switching Regulator Basics
- Types of Switching Regulators
- Advantages vs Disadvantages in Comparison with Linear Regulator
- Supplement-Current Paths during Synchronous Rectifying Step-Down Converter Operation
- Operating Principles of Buck Switching Regulator
- Differences between Synchronous and Nonsynchronous Rectifying DC-DC Conversion
- Control Methods (Voltage Mode, Current Mode, Hysteresis Control)
- Efficiency Improvements at Light Load for the Synchronous Rectifying Type
- Protective and Sequencing Functions
- Considerations on Switching Frequencies
- Behavior when Vin Falls Below Vout
- Supplement-Protective Function: Output Pre-bias Protection
- Seven Representative Power Supply Circuits: From Low-noise to Boost Specs
- Concluding Remarks
- What is a DC/DC Converter?
Design
- Overview of Selection of Inductors and Capacitors for DC-DC Converters
-
Overview of DC-DC Converter PCB Layout
- Ringing at switching nodes
- Placement of input capacitors and output diodes
- Placement of Thermal Vias
- Placement of Inductors
- Placement of Output Capacitors
- Feedback Path Wiring
- Ground
- Resistance and Inductance of Copper Foil
- Noise countermeasures: corner wiring, conducted noise, radiated noise
- Noise countermeasures: snubber, bootstrap resistor, gate resistor
- Summary
-
PCB Layout of a Step-Up DC-DC Converter – Introduction
- The Importance of PCB Layout Design
- Current Paths in Step-up DC-DC Converters
- PCB Layout Procedure
- Placement of Input Capacitors
- Placement of Output Capacitors and Freewheel Diodes
- Inductor Placement
- Placement of Thermal Vias
- Feedback Path Wiring
- Ground
- Layout for Synchronous Rectification Designs
- Resistance and Inductance of Copper Foil
- Relationship Between Corner Wiring and Noise
- Summary
Evaluation
- Overview of Characteristics and Evaluation Method of Switching Regulators
- How to Read Power Supply IC Datasheets: Cover, Block Diagram, Absolute Maximum Ratings and Recommended Operating Conditions
- Evaluating a Switching Regulator: Output Voltage
-
Introduction
- Definitions and Heat Generation
- Losses in Synchronous Rectifying Step-Down Converters
- Conduction Losses in Synchronous Rectifying Step-Down Converters
- Switching Losses in Synchronous Rectifying Step-Down Converters
- Dead Time Losses in Synchronous Rectifying Step-Down Converters
- Controller IC Power Consumption Losses in a Synchronous Rectifying Step-Down Converter
- Gate Charge Losses in a Synchronous Rectifying Step-Down Converter
- Conduction Losses due to the Inductor DCR
- Example of Power Loss Calculation for a Power Supply IC
- Simplified Method of Loss Calculation
- Heat Calculation for Package Selection: Example 1
- Heat Calculation for Package Selection: Example 2
- Loss Factors
- Matters to Consider When Studying Miniaturization by Raising the Switching Frequency
- Important Matters when Studying High Input Voltage Applications
- Important Matters when Studying Large Output Currents Applications: Part 1
- Important Matters when Studying Large Output Currents Applications: Part 2
- Summary
Application
-
Important Points in the Design of a Power Supply Using a Linear Regulator
- Typical Application Circuit Examples of Linear Regulator ICs
- Input/output capacitor design and ripple prevention for linear regulator ICs
- How to determine efficiency and Thermal design for linear regulator ICs
- Protection of Linear Regulator IC Terminals
- Soft Starting of a Linear Regulator IC
- Overcurrent Protection(OCP) and Thermal Shutdown(TSD) of Linear Regulator IC
-
Important Points in the Design of a Power Supply Using a Floating Type Linear Regulator
- Example of Power Supply Circuit Based on a Floating Type Linear Regulator IC
- Input/output capacitor design and ripple prevention for linear regulator ICs
- How to determine efficiency and Thermal design for Floating Type Linear Regulator ICs
- Terminal protection for linear regulator ICs
- Startup characteristics for linear regulator ICs
- Failure to Start of a Power Supply Using a Linear Regulator, Case 1: Damage to the IC and Peripheral Components Due to Hand-Soldering
- About Parallel Connections of LDO Linear Regulators
-
Introduction
- Power Supply Sequence Specification ①: Power Supply Sequence Specifications and Control Block Diagrams
- Power Supply Sequence Specification①: Sequence Operation at Power Turn-on
- Power Supply Sequence Specification①: Sequence Operation at Power Shutoff
- Power Supply Sequence Specification①: Example of Actual Circuit and Component Value Calculations
- Power Supply Sequence Specification①: Example of Actual Operations
- Power Supply Sequence Specification②:Power Supply Sequence Specifications and Control Block Diagrams
- Power Supply Sequence Specification②:Sequence Operation at Power Turn-on
- Power Supply Sequence Specification②: Sequence Operation at Power Shutoff
- Power Supply Sequence Specification②: Example of Actual Circuit and Component Value Calculations
- Power Supply Sequence Specification②: Example of Actual Operations
- Circuits to Implement Power Supply Sequences Using General-Purpose Power Supply ICs ーSummaryー
- Easy Stabilization/Optimization Methods for Linear Regulators – Introduction
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