SBAA739 October   2025 LM2005 , LM2101 , LM2103 , LM2104 , LM2105 , UCC27444 , UCC27444-Q1 , UCC27517 , UCC27517A , UCC27517A-Q1

 

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Introduction

Traditional discrete gate driver implementation often adds unnecessary complexity, increase in board size, and introduces invariability in performance. The UCC27517A, UCC27444 and LM2x0x family of devices are cost effective, high-performance gate drivers ICs that directly address these challenges. By incorporating critical drive functions and protective features into a single IC, this reduces the need for extra components such as resistors, comparators, level shifters and bootstrap circuit.

These devices are optimized for low-to-mid voltage motor and power switching applications making them preferred for many cost sensitive applications: power tools, vacuum cleaners, battery disconnect systems and more.

By using the UCC27517A, UCC27444 and LM2X0X family of devices, designers drastically reduces BOM (bill of materials) count, simplify PCB layout and improve overall system reliability while preserving or improving performance while integrating a smart integrated approach to power design.

BJT Gate Driver TopologyFigure 1 BJT Gate Driver Topology

Challenges of Discrete Gate Driver Implementation

Designers frequently use discrete gate driver implementation to reduce upfront component costs. However, in practice this strategy involves a number of underlying problems that gradually eliminates any initial savings.

Across real world customer use cases, there are often the following pain points:

High BOM Count and Sourcing ChallengesComplex Layouts and Longer Design CyclesHigher Field Failure Rates and Reliability Risks
  • Requires six to 10+ components per channel
  • Involves resistors, transistors, level shifters, diodes, protection circuits
  • Increases sourcing burden across multiple vendors
  • Exposes design to supply chain volatility
  • Requires a larger board area
  • Requires careful wiring to avoid interference, ground loops, and noise
  • Reliable switching often needs multiple design/layout revisions
  • Adds technical workload and project delays
  • More components increase points of failure
  • Tolerance variations cause inconsistent behavior
  • Performance varies under temperature or voltage changes
  • Risk of shoot-through or undervoltage lockout if unmanaged

These challenges are especially greater in high volume and highly space-constrained applications like power tools, vacuum cleaners and battery powered system where board space, design time, and BOM cost are critical.

This is why integrated gate drivers such as UCC27517A, UCC27444 and LM2x0x series are gaining popularity. It addresses these issues head on by providing all of the necessary gate drive functions in a single small packaged, lower design complexity, boosting performance and lower system cost.

Background of Discrete Design

Discrete gate drivers are often organized with individual components to execute or realize key functions. A typical discrete gate driver employs an op-amp or comparator to detect the input control signal, transistors or logic gates to shift levels and buffer the signal and a bootstrap circuit (diodes and resistor) for high side switching. Gate resistors and Zener diodes are commonly used to adjust switching speed and protect the gate from voltage spikes. These components work together to create the voltage and timing required to turn the power MOSFET of IGBT on and off.

However, because each function is handled by a different component, the design necessitates precise coordination, matching and routing. Timing mismatch, parasitic interference and layout limitations can all have an impact on performance and reliability. This complexity is precisely what integrated gate drivers like the UCC27517A, UCC27444 and UCC21X series are intended to eliminate by merging all of these operations into a single small, efficient IC.\

Table 1 Difference Between Discrete and Integrated Design
FeaturesDiscrete Component DesignGate Driver IC solution (Intergrated)
UVLONo (requires further components)Integrated
Driver Current Independent of InputDirectly proportional to inputConsistent regardless of control input
Level ShiftingTypically requires 5+ extra componentsNo external circuitry required
Shoot Through ProtectionNoYes (Available, not necessary)
Noise ImmunityPoorExcellent
HS dV/dtUnknown, must watch layout and placementProvided in data sheet
Protection FeatureExtra component and spaceIntegrated option
CostHigherLower
BOM Count10+5

Layout Diagrams

Discrete LayoutFigure 2 Discrete Layout
Integrated LayoutFigure 3 Integrated Layout

Cost-Competitive Integrated Parts

Instead of creating a gate driver circuit from several discrete components, designers can use integrated gate driver ICs such as the UCC27517A, UCC27444 and LM2x0x series. These devices are intended to simplify the implementation of the gate driver by combining critical functionality like signal conditioning, level shifting and protection into a single, cost optimized, compact package.

UCC27517AUCC27444LM2x0x
  • Single Channel
  • UVLO
  • 4A/4A Peak Source & Sink
  • Dual Input +/-
  • Negative Voltage
  • Dual Channel
  • 4A/4A Peak Source & Sink
  • Enable Pin
  • 3-Volt Power Reset
  • Negative Voltage
  • Half Bridge
  • 0.5A/0.8A Peak source/sink current
  • Boot strap diode option
  • 5V/8V UVLO Option
  • Interlock Option
  • Inverting Input Option
UCC27517A: DBV PackageFigure 4 UCC27517A: DBV Package
Figure 5 UCC27444: DGN Package
Figure 6 LM2X0X: DSG Package