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Home > Products > Integrated Circuits (ICs) > Power Management (PMIC) - Motor Drivers, Controllers > DRV8884PWPR
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DRV8884PWPR

In Stock 1098 pcs Reference Price(In US Dollars)
1+
$33.6341
Manufacturer Part Number:
DRV8884PWPR
Manufacturer / Brand
Texas Instruments
Part of Description:
IC MTR DRV BIPLR 0-5.3V 24HTSSOP
Datasheets:
DRV8884PWPR(1).pdfDRV8884PWPR(2).pdf
Lead Free Status / RoHS Status:
ROHS3 Compliant
Stock Condition:
New original, 1098 pcs Stock Available.
ECAD Model:
Ship From:
Hong Kong
Shipment Way:
DHL/Fedex/TNT/UPS

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Part Number DRV8884PWPR
Manufacturer / Brand Texas Instruments
Stock Quantity 1098 pcs Stock
Category Integrated Circuits (ICs) > Power Management (PMIC) - Motor Drivers, Controllers
Description IC MTR DRV BIPLR 0-5.3V 24HTSSOP
Lead Free Status / RoHS Status: ROHS3 Compliant
RFQ DRV8884PWPR Datasheets DRV8884PWPR Details PDF
DRV8884PWPR Details PDF for FR.pdf
DRV8884PWPR Details PDF for KR.pdf
DRV8884PWPR Details PDF for IT.pdf
DRV8884PWPR Details PDF for ES.pdf
DRV8884PWPR Details PDF for DE.pdf
Voltage - Supply 0V ~ 5.3V
Voltage - Load 8V ~ 37V
Technology Power MOSFET
Supplier Device Package 24-HTSSOP
Step Resolution 1 ~ 1/16
Series -
Package / Case 24-PowerTSSOP (0.173', 4.40mm Width)
Package Tape & Reel (TR)
Output Configuration Half Bridge (4)
Operating Temperature -40°C ~ 150°C (TJ)
Mounting Type Surface Mount
Motor Type - Stepper Bipolar
Motor Type - AC, DC -
Interface Logic
Function Driver - Fully Integrated, Control and Power Stage
Current - Output 1A
Base Product Number DRV8884
Applications General Purpose

Packaging & ESD

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Weight(KG): 0.00kg-1.00kg Price(USD$) : USD$60.00
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DRV8884PWPR Product Details:

The DRV8884PWPR is a highly versatile integrated circuit (IC) from Luminary Micro / Texas Instruments, designed for driving a wide range of bipolar stepper motors. As a Power Management IC (PMIC) - Motor Driver and Controller, this device addresses the challenges of efficiently and reliably controlling stepper motor applications.

The DRV8884PWPR features a fully integrated design, combining the control and power stage functions in a single package. This integration helps reduce system complexity, component count, and overall system cost. The device supports a wide input voltage range of 8V to 37V, making it suitable for a variety of general-purpose applications.

One of the key advantages of the DRV8884PWPR is its ability to provide a maximum output current of 1A, enabling it to drive a wide range of bipolar stepper motors. The device also offers a step resolution of 1 to 1/16, providing precise control and smooth motor operation.

The DRV8884PWPR is designed to be surface-mounted and is packaged in a 24-HTSSOP (Exposed Pad) enclosure, which helps with heat dissipation and overall thermal management. The device is RoHS-compliant and operates within a wide temperature range of -40°C to 150°C, making it suitable for use in diverse environmental conditions.

In terms of compatibility, the DRV8884PWPR can be used in a variety of general-purpose applications, including industrial automation, robotics, medical equipment, and consumer electronics. It is a direct replacement for the DRV8884PWPR, offering a similar set of features and performance characteristics.

While there may be other equivalent or alternative models available from different manufacturers, the DRV8884PWPR stands out as a reliable and versatile solution for stepper motor control applications, providing a comprehensive set of features and capabilities to meet the demands of various industries and applications.

DRV8884PWPR Key Technical Attributes

Bipolar Motor Driver Power MOSFET Logic

Surface Mount 24-HTSSOP

Current - Output: 1A

DRV8884PWPR Packing Size

24-HTSSOP package

Digi-Reel packaging

Dimensions: 0.173”, 4.40mm Width Exposed Pad

DRV8884PWPR Application

General Purpose motor driving applications

DRV8884PWPR Features

The DRV8884PWPR from Texas Instruments is designed for driving bipolar stepper motors. It includes an advanced power MOSFET technology which enhances the performance by improving power efficiency and reducing operational heat. The driver operates over a voltage range of 8 V to 37 V and can supply a continuous output current up to 1A. It is integrated with a fully complete control and power stage function, making it versatile for various motor driving purposes. The step resolution can be adjusted between 1 and 1/16, allowing precise motor control. Interface logic is provided, supporting voltages from 0 V to 5.3 V for versatile interfacing with other circuit components.

DRV8884PWPR Quality and Safety Features

Lead-free and RoHS Compliant

MSL 3 (168 Hours) which ensures reliability in moisture-sensitive applications

DRV8884PWPR Compatibility

Compatible with various bipolar stepper motors thanks to its configurable step resolution

Able to interface logically with different devices due to broad voltage range

DRV8884PWPR Datasheet PDF

For further detailed technical specifications, please download the most authoritative datasheet available on our website.

Quality Distributor

IC-Components is a premium distributor of Texas Instruments products like DRV8884PWPR. Be sure to obtain your quote through our website to guarantee access to top-tier components with excellent service.

Frequently Asked Questions

What are the primary design considerations when replacing an older bipolar stepper motor driver like the Allegro A4988 with the DRV8884PWPR in a new PCB layout, particularly concerning pin compatibility and driving current differences?
Replacing an A4988 with the DRV8884PWPR in a new PCB layout requires careful attention to pinout and thermal management. While both are bipolar stepper motor drivers, the DRV8884PWPR's 24-HTSSOP package and integrated control/power stage offer different pin assignments than the A4988. The DRV8884PWPR offers up to 1A continuous output current, which may be sufficient for applications previously driven by the A4988, but verify load requirements. Ensure the DRV8884PWPR's exposed pad is properly soldered to the PCB for effective heat dissipation, especially if the original design relied solely on PCB traces for thermal management.
For an industrial automation system requiring precise microstepping up to 1/16, how does the DRV8884PWPR's step resolution and internal current limiting compare to higher-end dedicated microstepping controllers, and what are the practical implications for motor torque ripple?
The DRV8884PWPR provides step resolutions from full step to 1/16 microstepping, suitable for many general-purpose applications. For industrial systems demanding the absolute highest precision and minimal torque ripple, particularly at lower speeds or with very sensitive actuators, dedicated microstepping controllers might offer more advanced current decay modes (e.g., mixed decay) or higher internal resolution for smoother current waveforms. The DRV8884PWPR's integrated solution simplifies design, but in extremely critical applications, engineers should evaluate its current ripple performance against alternative, potentially more complex, ICs.
When integrating the DRV8884PWPR into a system with a 3.3V microcontroller, what are the critical interface voltage level considerations and potential issues to be aware of to avoid damaging the DRV8884PWPR's logic inputs?
The DRV8884PWPR accepts a wide logic supply voltage range from 0V to 5.3V. When interfacing with a 3.3V microcontroller, ensure that the microcontroller's output logic levels are compatible with the DRV8884PWPR's input thresholds. Generally, 3.3V logic outputs will be recognized by the DRV8884PWPR's inputs. However, it is crucial to consult the DRV8884PWPR datasheet for specific VIH (Voltage Input High) and VIL (Voltage Input Low) specifications to confirm reliable operation and prevent any potential damage, especially if the microcontroller's output voltage can slightly exceed 3.3V.
In a battery-powered portable device, what are the power supply requirements and potential inefficiencies of the DRV8884PWPR when driving a bipolar stepper motor from an 8V to 37V load supply, and are there any specific bypass capacitor strategies recommended for optimal power delivery?
The DRV8884PWPR operates with a load supply voltage range of 8V to 37V, suitable for a variety of battery-powered applications. For optimal performance and to mitigate power supply noise, especially with pulsed motor loads, it's highly recommended to place bypass capacitors (e.g., ceramic and electrolytic) as close as possible to the DRV8884PWPR's VMA and VMB (motor supply) pins. The efficiency will be dependent on the motor's impedance, the chosen current limit, and the stepping mode. Minimizing the loop area of the motor drive current is key to reducing inductance-related losses and improving overall efficiency.
For long-term operation in a demanding environment with ambient temperatures up to 60°C, what are the thermal management considerations for the DRV8884PWPR in its HTSSOP24 package, and what is the maximum continuous output current achievable under these conditions without exceeding the TJ of 150°C?
Operating the DRV8884PWPR in a 60°C ambient environment requires careful thermal design. The DRV8884PWPR has a maximum junction temperature (TJ) of 150°C. With a thermal resistance (RthJA) for the HTSSOP24 package typically around 40-50°C/W (depending on PCB layout and copper pour), the maximum allowable power dissipation will be limited. To maintain operation below 150°C TJ, the continuous output current of 1A may need to be derated. A significant copper pour on the PCB connected to the exposed thermal pad of the DRV8884PWPR is essential for effective heat sinking. Engineers should perform thermal simulations or actual measurements to determine the safe operating current at 60°C ambient.
Is the DRV8884PWPR a suitable replacement for the TI DRV8825 in a 3D printer control board where the DRV8825 was used for its higher current output and adjustable current limiting? What are the key differences and potential design modifications required?
The DRV8884PWPR is not a direct drop-in replacement for the TI DRV8825, although both are bipolar stepper motor drivers. The DRV8825 typically offers a higher continuous output current (up to 2.2A) and often has more advanced current control features. The DRV8884PWPR is rated for 1A continuous output current. If your 3D printer application was pushing the limits of the DRV8825's current capability, the DRV8884PWPR may not provide sufficient power. You would need to re-evaluate the stepper motor's current draw. Additionally, pinout and control interfaces might differ, requiring PCB layout modifications.
What are the implications of using the DRV8884PWPR in applications requiring very low standby current, and how does its quiescent current compare to other motor driver ICs often used in power-sensitive portable equipment?
The DRV8884PWPR is designed for general-purpose motor driving and may not be the optimal choice for applications where extremely low standby current is a primary concern. While specific quiescent current figures are in the datasheet, dedicated ultra-low-power motor drivers often exhibit significantly lower standby consumption. If your application requires minimal power drain when the motor is inactive, consider evaluating alternative PMICs or motor drivers specifically engineered for battery-powered devices with aggressive power management features. The DRV8884PWPR's functionality as a fully integrated control and power stage means its quiescent current will be higher than a simpler, non-integrated driver.
When configuring the step resolution of the DRV8884PWPR, what are the recommended methods and potential pitfalls of setting the MODE0, MODE1, and MODE2 pins for optimal microstepping performance in a robotic arm application?
The DRV8884PWPR uses three logic input pins (MODE0, MODE1, MODE2) to set the step resolution from full step (1/1) to 1/16 microstepping. To achieve 1/16 microstepping, these pins typically need to be configured to a specific high/low logic combination as detailed in the DRV8884PWPR datasheet. When setting these pins, ensure they are properly driven by the microcontroller and that the signals are stable. Incorrect configuration can lead to unexpected motor movement or reduced step resolution. It's crucial to connect these pins to the microcontroller's GPIOs and ensure the microcontroller code correctly sets their states before enabling the motor driver.
For systems that operate in harsh environments with potential for significant voltage transients on the power rails, what are the robust ESD (Electrostatic Discharge) protection mechanisms built into the DRV8884PWPR, and are there any external component recommendations to enhance system-level ESD immunity for the DRV8884PWPR?
The DRV8884PWPR incorporates internal ESD protection structures on its pins to withstand typical electrostatic discharge events during handling and operation. However, for applications in harsh industrial environments with a high risk of voltage transients, it is advisable to implement additional system-level ESD protection. This can include transient voltage suppressors (TVS diodes) on power supply lines and communication interfaces connected to the DRV8884PWPR. Careful PCB layout with adequate grounding and decoupling is also paramount in minimizing the impact of ESD events on the DRV8884PWPR and other sensitive components.
If a design originally used a competitor's integrated bipolar stepper motor driver with similar current and voltage ratings (e.g., a STMicroelectronics device), what are the most probable design challenges or differences to anticipate when migrating to the DRV8884PWPR, especially concerning its "General Purpose" application classification?
Migrating from a competitor's integrated bipolar stepper motor driver to the DRV8884PWPR, even with similar current and voltage ratings, can present design challenges. The "General Purpose" classification of the DRV8884PWPR suggests a broad feature set but may lack specific advanced functionalities found in application-specific drivers. Key differences might include the interface protocol (SPI vs. simple logic pins), the types of current decay modes implemented (if any), internal protection features, and thermal performance characteristics. Engineers should carefully compare the datasheets of the original part and the DRV8884PWPR, focusing on pinout, control signal logic, current control implementation, and protection features to identify potential redesign efforts.

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