Manufacturer Part Number
DRV8245HQRXZRQ1
Manufacturer
Texas Instruments
Introduction
The DRV8245HQRXZRQ1 is a motor driver specifically designed for power management of bipolar stepper motors and brushed DC motors, featuring advanced control and fully integrated power stages.
Product Features and Performance
Integrates driver, control, and power stage
Supports Bipolar and Brushed DC motor types
Dual half-bridge output configuration
Interfaces with PWM and SPI
Built with Bi-CMOS technology
High max output current of 32A
Operates across 4.5V to 35V load voltage range
Wide supply voltage range from 4.5V to 5.5V
Capable of operating in temperatures from -40°C to 125°C
Product Advantages
High current capacity suitable for demanding applications
Flexible control interfacing options for diverse application needs
Robust operation in extreme temperature environments
Key Technical Parameters
Motor Type: Bipolar, Brushed DC
Output Configuration: Half Bridge (2)
Interface: PWM, SPI
Output Current: 32A
Supply Voltage: 4.5V ~ 5.5V
Load Voltage: 4.5V ~ 35V
Operating Temperature: -40°C ~ 125°C
Quality and Safety Features
AEC-Q100 qualified for automotive applications
Over-temperature and over-current protection
Compatibility
Compatible with a wide range of bipolar stepper and brushed DC motors
Interface compatibility with systems using PWM or SPI communication
Suitable for automotive systems meeting AEC-Q100 standards
Application Areas
Automotive motor control systems
Industrial automation
Consumer electronics requiring robust motor control
Product Lifecycle
The product status is active
Not currently nearing discontinuation
Standard support for upgrades or replacements available
Several Key Reasons to Choose This Product
High integration reduces system complexity and improves reliability
Supports both stepper and DC motors increasing versatility
High output current capable of driving demanding motor applications
Automotive-grade quality ensures reliability in harsh environments
Wide operating voltage and temperature range provide robust performance under varied conditions