ISL6609A: Synchronous Rectified MOSFET Driver

The ISL6609, ISL6609A is a high frequency, MOSFET driver optimized to drive two N-Channel power MOSFETs in a synchronous-rectified buck converter topology. This driver combined with an Intersil ISL63xx or ISL65xx multiphase PWM controller forms a complete single-stage core-voltage regulator solution with high efficiency performance at high switching frequency for advanced microprocessors.

The IC is biased by a single low voltage supply (5V), minimizing driver switching losses in high MOSFET gate capacitance and high switching frequency applications. Each driver is capable of driving a 3nF load with less than 10ns rise/fall time. Bootstrapping of the upper gate driver is implemented via an internal low forward drop diode, reducing implementation cost, complexity, and allowing the use of higher performance, cost effective N-Channel MOSFETs. Adaptive shoot-through protection is integrated to prevent both MOSFETs from conducting simultaneously.

The ISL6609, ISL6609A features 4A typical sink current for the lower gate driver, enhancing the lower MOSFET gate hold-down capability during PHASE node rising edge, preventing power loss caused by the self turn-on of the lower MOSFET due to the high dV/dt of the switching node.

The ISL6609, ISL6609A also features an input that recognizes a high-impedance state, working together with Intersil multiphase PWM controllers to prevent negative transients on the controlled output voltage when operation is suspended. This feature eliminates the need for the schottky diode that may be utilized in a power system to protect the load from negative output voltage damage. In addition, the ISL6609A's bootstrap function is designed to prevent the BOOT capacitor from overcharging, should excessively large negative swings occur at the transitions of the PHASE node.

Key Features
  • Drives Two N-Channel MOSFETs
  • Adaptive Shoot-Through Protection
  • 0.4Ω On-Resistance and 4A Sink Current Capability
  • Supports High Switching Frequency
    • Fast Output Rise and Fall
    • Ultra Low Three-State Hold-Off Time (20ns)
  • ISL6605 Replacement with Enhanced Performance
  • BOOT Capacitor Overcharge Prevention (ISL6609A)
  • Low VF Internal Bootstrap Diode
  • Low Bias Supply Current
  • Enable Input and Power-On Reset
  • QFN Package
    • Compliant to JEDEC PUB95 MO-220 QFN-Quad Flat No Leads-Product Outline
    • Near Chip-Scale Package Footprint; Improves PCB Efficiency and Thinner in Profile
  • Pb-Free (RoHS Compliant)
Applications
  • Core Voltage Supplies for Intel® and AMD® Microprocessors
  • High Frequency Low Profile High Efficiency DC/DC Converters
  • High Current Low Voltage DC/DC Converters
  • Synchronous Rectification for Isolated Power Supplies
Typical Diagram
Application Notes
TitleTypeUpdatedSizeOther Languages
AN1116: Elantec CMOS applicationsPDF13 Nov 2014231 KB
Datasheets
TitleTypeUpdatedSizeOther Languages
ISL6609, ISL6609A DatasheetPDF17 Nov 20141.63 MB
Tech Briefs
TitleTypeUpdatedSizeOther Languages
TB363: Guidelines for Handling and Processing Moisture Sensitive Surface Mount Devices (SMDs)PDF13 Jan 201529 KB
TB458: Converting a Fixed PWM to an Adjustable PWMPDF19 Nov 2014147 KB
White Papers
TitleTypeUpdatedSizeOther Languages
Five Easy Steps to Create a Multi-Load Power SolutionPDF30 Jan 2017502 KB
Order Information
Part NumberPackage TypeWeight(g)PinsMSL RatingPeak Temp (°C)RoHS Status
ISL6609ACBZ8 Ld SOIC0.07683260RoHS
ISL6609ACBZ-T8 Ld SOIC T+R0.07683260RoHS
ISL6609ACRZ8 Ld QFN0.02283260RoHS
ISL6609ACRZ-T8 Ld QFN T+R0.02283260RoHS
ISL6609AIBZ8 Ld SOIC0.07683260RoHS
ISL6609AIBZ-T8 Ld SOIC T+R0.07683260RoHS
ISL6609AIRZ8 Ld QFN0.02283260RoHS
ISL6609AIRZ-T8 Ld QFN T+R0.02283260RoHS
ISL6609AIRZ-TK8 Ld QFN T+R0.02283260RoHS
ISL6609, ISL6609A Datasheet 17 Nov 2014
8 Ld SOIC T+R ISL84514
8 Ld QFN T+R ISL6605
ISL6609
AN1116: Elantec CMOS applications 13 Nov 2014
TB363: Guidelines for Handling and Processing Moisture Sensitive Surface Mount Devices (SMDs) 13 Jan 2015
TB458: Converting a Fixed PWM to an Adjustable PWM 19 Nov 2014
Five Easy Steps to Create a Multi-Load Power Solution 30 Jan 2017