AMIS-30543 stepper motor driver carrier, bottom view with dimensions.
This product is a carrier board or breakout board for ON Semiconductor’s AMIS-30543 Micro-Stepping Motor Driver; we therefore recommend careful reading of the AMIS-30543 datasheet (495k pdf) before using this product. This stepper motor driver lets you control one bipolar stepper motor at up to 3 A output current per coil (see the Power Dissipation Considerations section below for more information). Here are some of the board’s key features:
- Standard step and direction control interface
- SPI interface for configuring settings (e.g. step mode, current limit, sleep) and reading status registers
- Speed and load angle output that can be used for stall detection or closed-loop control of the torque and speed based on the load angle
- Eleven different step modes: full-step (uncompensated, compensated 1-phase, or compensated 2-phase), half-step (uncompensated or compensated), 1/4-step, 1/8-step, 1/16-step, 1/32-step, 1/64-step, and 1/128-step
- SPI-programmable current control (from 132 mA to 3 A) enables your microcontroller to adjust the peak-current limit on the fly as more or less torque or speed is needed
- Intelligent chopping control that automatically selects the correct current decay mode (fast decay or slow decay)
- Low-EMI PWM with SPI-selectable voltage slopes
- Compatible with 5 V and 3.3 V microcontrollers
- Integrated 5V regulator that can be used to supply an external microcontroller
- Integrated watchdog function
- Open coil detection
- Thermal warning indicates when the driver is close to the thermal shutdown temperature
- Over-current status and shutdown (short-to-ground and shorted-load protection)
- Reverse voltage protection
Note: This driver needs to be enabled and configured through its SPI interface on power up, so your microcontroller must be capable of acting as an SPI master (either with an SPI peripheral or software SPI).
This product ships with all surface-mount components—including the AMIS-30543 driver IC—installed as shown in the product picture. However, soldering is required for assembly of the included through-hole parts. The following through-hole parts are included:
- One 1×20-pin breakaway 0.1″ male header
- Three 2-pin, 3.5 mm terminal blocks (for board power and motor outputs)
- One 0.1″ shorting block (for connecting IOREF to neighboring VDD pin)
The 0.1″ male header can be broken or cut into smaller pieces as desired and soldered into the smaller through-holes. These headers are compatible with solderless breadboards, 0.1″ female connectors, and our premium and pre-crimped jumper wires. The terminal blocks can be soldered into the larger holes to allow for convenient temporary connections of unterminated power and stepper motor wires. You can also solder your motor leads and other connections directly to the board for the most compact installation.
Using the driver
|VMOT||Reverse-protected 6 V to 30 V board power supply connection. Note: Available VDD current is reduced for input voltages under 8 V, and sleep mode is not available for input voltages under 9 V.|
|VBB||This pin gives access to the motor power supply after the reverse-voltage protection MOSFET (see the board schematic below). It can be used to supply reverse-protected power to other components in the system. It is generally intended as an output, but it can also be used to supply board power.|
|GND||Ground connection points for the motor power supply and control ground reference.|
|MOTXP||Motor output: “positive” end of phase X coil.|
|MOTXN||Motor output: “negative” end of phase X coil.|
|MOTYP||Motor output: “positive” end of phase Y coil.|
|MOTYN||Motor output: “negative” end of phase Y coil.|
|VDD (5V OUT)||The board is powered by an internal 5V regulator, and this pin gives access to the regulated 5 V output. This can be used to supply the neighboring IOREF pin when using this board in 5V systems, and it can be used to power an external microcontroller. When VMOT is over 8 V, approximately 30 mA is available for external components; when VMOT is less than 8 V, the available current drops to less than 10 mA.|
|IOREF||All of the board signal outputs (except SLA) are open-drain outputs that are pulled up to IOREF, so this pin should be supplied with the logic voltage of the controlling system (e.g. 3.3V for use in 3.3V systems). For convenience, it can be connected to the neighboring VDD pin when it is being used in a 5V system.|
|NXT||Changes on this input move the motor current one step up or down in the translator table (even when the motor is disabled). The edge that triggers the step depends on the NXT-polarity configuration bit, which can be changed through the SPI interface (rising edge by default).|
|DIR||Input that determines the direction of rotation. The direction can also be controlled through the SPI interface.|
|DO||SPI data output. (This pin is also often referred to as “MISO”.)|
|DI||SPI data input. (This pin is also often referred to as “MOSI”.)|
|CLK||SPI clock input.|
|CS||SPI chip select input. Logic transitions on this pin are required for SPI communication, even if this is the only device on the SPI bus.|
|CLR||Chip reset input. A logic high on this input clears all internal registers, except in sleep mode.|
|ERR||Error output. This pin drives low to indicate that an error condition has occurred. The specific error can be determined by using the SPI interface to check the error flags.|
|POR/WD||Power-on reset/watch dog function output. This pin provides an active-low signal that can be used as a reset input for an external microcontroller.|
|SLA (filtered)||SLA (speed and load angle) output after a low-pass filter. The result is an analog voltage between 0 V and 5 V that indicates the level of the back-EMF voltage of the motor. This signal can be used for stall detection or closed-loop control of the torque and speed based on the load angle. Note: Since the output of this pin ranges from 0 V to 5 V regardless of IOREF, extra precautions should be taken when connecting this pin to a 3.3V device (such as passing it through an appropriate voltage divider).|
General minimal wiring diagram
Minimal wiring diagram for connecting a microcontroller to an AMIS-30543 stepper motor driver carrier.
While the AMIS-30543 allows control of a stepper motor through a simple step (NXT) and direction (DIR) interface, it first needs to be enabled and configured through its SPI interface. This means that the controlling microcontroller must be capable of acting as an SPI master (either with an SPI peripheral or software SPI), and it must be connected to the DI, CLK, and CS pins. While the DO and ERR pins are not required to use this driver, it is generally a good practice to use them to monitor for error conditions.
Minimal wiring diagram (5 V systems only)
Minimal wiring diagram for connecting a microcontroller with a logic voltage of 5 V to an AMIS-30543 stepper motor driver carrier.
The AMIS-30543 has an internal 5 V regulator that can be used to supply IOREF in cases where the board is being used in 5 V systems. This internal regulator can also be used to supply the external microcontroller’s logic voltage if the regulator can deliver the required current, in which case there would be a wire from the AMIS-30543 VDD to the microcontroller VDD in the above diagram, and the “logic power supply” box would not be present.
Arduino library and example code
Controlling an AMIS-30543 stepper motor driver carrier with an Arduino-compatible #3104 A-Star 32U4 Mini SV.
If you are new to the AMIS-30543 or stepper motors in general, our AMIS-30543 Arduino library can help you get started. The library provides basic functions for configuring and operating the driver using an Arduino or Arduino-compatible controller. It also provides access to many of the driver’s advanced features and includes example sketches that show you how to use them.
Power dissipation considerations
The AMIS-30543 driver IC has a maximum current rating of 3 A per coil, but the actual current you can deliver depends on how well you can keep the IC cool. The carrier’s printed circuit board is designed to draw heat out of the IC, but to supply more than approximately 1.8 A per coil continuously, a heat sink or other cooling method is required. However, it is possible to use the SPI-configurable current limit to selectively deliver higher currents than this for short durations without overheating the driver.
This product can get hot enough to burn you long before the chip overheats. Take care when handling this product and other components connected to it.
Since the input voltage to the driver can be significantly higher than the coil voltage, the measured current on the power supply can be quite a bit lower than the coil current (the driver and coil basically act like a switching step-down power supply). Also, if the supply voltage is very high compared to what the motor needs to achieve the set current, the duty cycle will be very low, which also leads to significant differences between average and RMS currents.
AMIS-30543 stepper motor driver carrier schematic diagram.
This diagram is also available as a downloadable pdf: AMIS-30543 stepper motor driver carrier schematic (231k pdf)
|Size:||1.0″ × 1.2″|
|Minimum operating voltage:||6 V2|
|Maximum operating voltage:||30 V|
|Continuous current per phase:||1.8 A3|
|Maximum current per phase:||3 A4|
|Minimum logic voltage:||2.5 V|
|Maximum logic voltage:||5.5 V|
|Microstep resolutions:||full, 1/2, 1/4, 1/8, 1/16, 1/32, 1/64, 1/128|
|Reverse voltage protection?:||Y|
- ON Semiconductor AMIS-30543 stepper motor driver datasheet (495k pdf)
- AMIS-30543 stepper motor driver carrier schematic diagram (231k pdf)
- Printable schematic diagram of the AMIS-30543 Motor Driver Carrier.
- Dimension diagram of the AMIS-30543 Stepper Motor Driver Carrier (437k pdf)
- 3D model of the AMIS-30543 Stepper Motor Driver Carrier (4MB step)
- Drill guide for the AMIS-30543 Stepper Motor Driver Carrier (50k dxf)
- This DXF drawing shows the locations of all of the board’s holes.
- AMIS-30543 application note: how to measure Bemf on the SLA-pin (1MB PDF)
- This application note from ON Semiconductor explains how to use the Speed and Load Angle (SLA) output to build accurate stall-detection and torque-adaptive algorithms.
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