1062_1B - PhidgetStepper Unipolar 4-Motor

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Quick Overview

Accurately control up to 4 unipolar stepper motors with this controller. Connects to a USB port.
1062_1B - PhidgetStepper Unipolar 4-Motor

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  • 1062_1B - PhidgetStepper Unipolar 4-Motor
  • 1062_1B - PhidgetStepper Unipolar 4-Motor


Note: The 1062_1B is identical to the 1062_1, except that you have the option of whether you want to include the USB cable.

The PhidgetStepper Unipolar allows you to control the position, velocity, and acceleration of up to 4 unipolar stepper motors. The 1062 can be used in applications that require precise positioning and continuous rotation, at low cost.

Note: Because most unipolar motors are resistive limitied, the 1062 does not support current control. If your motor requires current control, have a look at the 1067 - PhidgetStepper Bipolar HC.


Comes Packaged with

  • A Hardware mounting kit (4 nuts and bolts (M3), 4 plastic spacers)


warning Make sure the power supply is unplugged before attaching or removing wires from the terminal blocks. Failure to do so could cause permanent damage to the PhidgetStepper board.

Related Videos

Product Specifications

Controller Properties
API Object Name Stepper
Motor Type Unipolar Stepper
Number of Motor Ports 4
Motor Position Resolution 12 Step (40-Bit Signed)
Position Max ± 5.49756E+11 ½ steps
Stepper Velocity Resolution 0.75 ½ steps/sec
Stepper Velocity Max 383.3 ½ steps/sec
Stepper Acceleration Resolution 140.6 ½ steps/sec²
Stepper Acceleration Min 140.6 ½ steps/sec²
Stepper Acceleration Max 8895.4 ½ steps/sec²
Board Properties
Controlled By USB
API Object Name Stepper
Electrical Properties
Available Current per Coil Max 1 A
Supply Voltage Min 5 V DC
Supply Voltage Max 12 V DC
Current Consumption Min 23 mA
Current Consumption Max 100 mA
USB Speed Full Speed
Physical Properties
Power Jack Hole Diameter 5.5 mm
Power Jack Pin Diameter 2.1 mm
Power Jack Polarity Center Positive
Recommended Wire Size (Motor Terminal) 16 - 26 AWG
Recommended Wire Size (Power Terminal) 12 - 24 AWG
Operating Temperature Min 0 °C
Operating Temperature Max 70 °C


Welcome to the 1062 user guide! In order to get started, make sure you have the following hardware on hand:

Next, you will need to connect the pieces:

1062 0 Connecting the Hardware.jpg
  1. Connect the stepper motor to one of the inputs on the PhidgetStepper board. If you are having difficulty connecting the wires, refer to the technical section.
  2. Connect the power supply to the Phidget using the barrel connector.
  3. Power supplies with higher current (more than 2.5 Amps) should be wired directly into the terminal block.
  4. Connect the Phidget to your PC using the USB cable.

Now that you have everything together, let's start using the 1062!

Using the 1062

Phidget Control Panel

In order to demonstrate the functionality of the 1062, the Phidget Control Panel running on a Windows machine will be used.

The Phidget Control Panel is available for use on both macOS and Windows machines. If you would like to follow along, first take a look at the getting started guide for your operating system:

Linux users can follow the getting started with Linux guide and continue reading here for more information about the 1062.

First Look

After plugging the 1062 into your computer and opening the Phidget Control Panel, you will see something like this:

1062 Panel.jpg

The Phidget Control Panel will list all connected Phidgets and associated objects, as well as the following information:

  • Serial number: allows you to differentiate between similar Phidgets.
  • Channel: allows you to differentiate between similar objects on a Phidget.
  • Version number: corresponds to the firmware version your Phidget is running. If your Phidget is listed in red, your firmware is out of date. Update the firmware by double-clicking the entry.

The Phidget Control Panel can also be used to test your device. Double-clicking on an object will open an example.

Stepper Motor

Double-click on the Stepper object, labelled Unipolar Stepper Controller, in order to run the example:

1062 Stepper Example.jpg

General information about the selected object will be displayed at the top of the window. You can also experiment with the following functionality:

  • Toggle the Engage button to provide power to the motor coils.
  • By default, motor position, velocity, and acceleration are measured in sixteenths of a step. If you want to use different units, change the value in the Rescale Factor textbox.
  • Use the Target Position slider to set a new target position. Change the Acceleration and Velocity sliders to speed up or slow down the 1062's approach.
  • Select the Velocity (Continuous) Control tab for continuous rotation instead of specifiying a position.


Technical Details

How to Connect your Stepper to the 1062

Unipolar Stepper motors are available in 5, 6 or 8 wire configurations.

5 Wire Stepper Motors

In a 5 wire motor, the center taps of the coils are connected together. This scheme prevents this motor from being controlled as a bipolar motor.

To use a 5 wire motor as a unipolar, the center tap wire is connected to the power supply.

Determining how to connect a 5 wire stepper to a Unipolar Stepper Controller, like the 1062 can be done by following this procedure.

Start by measuring the resistance between all the wires. Below is a sample table of resistance data, in ohms. This table contains example values, your readings may be different but should still produce a similar pattern.

1062 1 Motor Types 5wire.jpg


Wire ColorBlueGreenRedYellowPurple
Blue   147 74 147 147
Green     74 147 147
Red       74 74
Yellow         147

Looking at the table, you should notice a pattern; the red wire has the same resistance to the other four wires. This tells us that red is our + (center tap) wire, and should be wired to the power supply connection. On the 1062 PhidgetStepper, the power supply connection is labelled as (+). There are two power supply connections available on the 1062 for each motor - either can be used. Disconnect the power from the board and connect the center tap wire to the (+) connection.

Pick one of the remaining four wires and wire it to the A terminal, and connect the other wire for that coil to the B terminal. Connect the remaining wires to C and D. The motor should work regardless of which wire is connected to C and which is in D, but one of these combinations will result in a clockwise rotation for increasing position and counter-clockwise rotation for decreasing position, and the other will produce the opposite rotation.

6 Wire Stepper Motors

The process is similar to a 5 wire motor. On a 6 – wire motor, there will be two + wires, one for each coil, which are the center taps for each coil. You will need to isolate which are the center tap wires and the corresponding wires for their coil.

These center taps must be wired together to the power supply.

Let’s assume our six wire stepper motor wires are colored as follows: red, green, black, white, brown, and yellow.

We measure the resistance between all wires and are presented with the following values in ohms (these are simply example values) :

  1062 1 Motor Types 6wire.jpg


Wire ColorWhiteRedBlueGreenPurpleYellow
White   10 10
Red     10 10
Blue       20
Purple           20

Looking at our table, we can see our pattern. The white wire has the same resistance to the purple and yellow wires. The red wire has the same resistance to the blue and green wires. White, purple, and yellow bring out one coil, and red, blue, and green are the other coil. The red and white wires are the center of their coils.

Disconnect the power from the board and connect the red and white wires to the (+) terminal block connections on the PhidgetStepper. Pick one of the remaining four wires and wire it to the A terminal, and connect the other wire for that coil to the B terminal. Connect the remaining wires to C and D. The motor should work regardless of which wire is connected to C and which is in D, but one of these combinations will result in a clockwise rotation for increasing position and counter-clockwise rotation for decreasing position, and the other will produce the opposite rotation.

8 Wire Stepper Motors

8 Wire Motors are very difficult to wire up if you do not have a schematic showing how the wires are connected to the internal coils. Only follow these instructions if you are really desperate. In an 8 wire motor, the coils are split, and to operate it as a unipolar, we have to reconnect the coils to reduce it to a 6 wire unipolar.

Assume our eight wire stepper motor wires are colored as follows: Orange, blue, red, green, brown, yellow, white and purple. In an 8-wire stepper motor, these wires would be part of 4 coils, 2 wires per coil. We need to determine the cable pairings.

We measure the resistance between each wire and are presented with the following values in ohms (these are simply example values):


1062 1 Motor Types 8wire.jpg
Wire ColorOrangeRedYellowPurpleBlueGreenBrownWhite
Orange   1
Red     1
Yellow       1
Purple         1

This table tells us which wires are parts of a coil. From the table we can tell that orange/blue, green/red, brown/yellow, and white/purple are the coils.

Of each pair, one of the wires will be assigned to A, B, C, or D, and the other wire will be connected to another pair. The number of combinations to be tried to see if they produce rotation is large, but can be reduced to a maximum of 96 possibilities by following these steps:

  1. Choose Red/Blue to connect to A. (2 possibilities)
  2. Choose one wire of the other pairs (6 possibilities) and connect to B. The other wire from this pair is connected to the wire from Step 1 not connected to A.
  3. Choose one wire from the two remaining pairs (4 possibilities) and connect to C.
  4. Choose one wire from the remaining pair (2 possibilities) and connect to the wire from Step 3 not connected to C. The remaining wire from this pair is connected to D.
  5. After trying each permutation, engage the motor from software and try to rotate it. Since you are driving the motor as Unipolar, the connected pairs should be connected to the (+) on the PhidgetStepper Controller.
  6. If you attempt to use this algorithm, build a table of permutations beforehand and proceed in a systematic way.

There are a total of 96 wiring combinations, of which there are 2 valid combinations where one will cause a clockwise motor rotation and the other will cause a counter-clockwise rotation.

In order to properly determine the proper wiring for your motor we suggest consulting any manuals or data sheets that are associated with your particular motor.

Controlling Steppers

Stepper motors precision are limited by the manufacturing process used to build them. Errors in the rotor and coils will cause some degree of inaccuracy. In our experience, inexpensive stepper motors will often have positioning errors approaching a half-step.

Since stepper motors do not have the inherent ability to sense their actual shaft position, they are considered open loop systems. This means that the value contained in the current position property is merely a count of the number of steps that have occurred towards the target value; it can not be relied upon as a measure of the actual shaft angle, as the motor can occasionally understep or overstep due to forces such as inertia.

For many applications, it is acceptable for the motor to miss a few steps. In applications where positional accuracy is vital, there are several ways of overcoming this drawback. The simplest is to allow the motor load to depress a limit switch located at a known position. This can be used to fire an event in software to recalibrate the shaft position values. A more elegant solution might involve the mounting of an optical encoder on the shaft and the development of a control system.

Stepping Mechanism

The 1062 PhidgetStepper Unipolar controls stepper motors in half-step increments. A Position increment of one corresponds to one half-step. A stepper motor with 15 degree step increments will rotate in 7.5 degree steps. The 1062 accomplishes this by alternating the number of powered coils between one and two, always at least one coil powered. In this way, the rotor is positioned at both full steps and half steps. The table below describes the order in which coils are powered to achieve this.

Step NumberCoil ACoil BCoil CCoil DShaft Angle
4 OFF OFF OFF ON 22.5º
6 OFF ON OFF OFF 37.5º
8 OFF OFF ON OFF 52.5º

After step number 8 in the table, the order the coils are powered in simply repeats from the beginning. As the motor approaches the requested position, it is decelerated according to the value of the acceleration property. When the desired position has been reached, the 1062 stops the motor and holds it at that position.

Synchronization of Multiple Motors

Many applications call for several steppers motors operating in unison - for example, operating a CNC table, or a robot arm. Highly precise synchronization of steppers using the PhidgetStepper is not possible, as the sequencing will be affected by the real-time performance of your operating system. Each stepper is controlled as a independent unit, so there is no way of arranging for a particular action to happen to all motors at the same time. Typical jitter can be 10-30ms.

Compatibility Guidelines

When looking for a motor that will be compatible with the 1062, check the motor's data sheet and make sure it meets the following specifications.

  • Unipolar motor - The 1062 can only be used with resistive-limited unipolar stepper motors.
  • 5, 6, or 8-wire motor - A 4-wire motor cannot be used with the 1062, because the centre taps of the coils are not exposed.
  • Rated/Recommended Voltage - If the motor comes with a rated or recommended voltage, it should be no more than 12 volts, and you should use a power supply that can output that voltage.
  • Rated Current - The motor should be rated for a maximum of 1A per coil.

Further Reading

For more information about stepper motors and how they work, check the Stepper Motor and Controller Primer.

What to do Next

  • Software Overview - Find your preferred programming language here to learn how to write your own code with Phidgets!
  • General Phidget Programming - Read this general guide to the various aspects of programming with Phidgets. Learn how to log data into a spreadsheet, use Phidgets over the network, and much more.
  • Phidget22 API - The API is a universal library of all functions and definitions for programming with Phidgets. Just select your language and device and it'll give you a complete list of all properties, methods, events, and enumerations that are at your disposal.


Additional Information

SKU ES000034
Manufacturer Phidgets

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