The utility will automatically determine the right driver for your system as well as download and install the Initio INIC-950 driver. Being an easy-to-use utility. Free drivers for Initio INIC-950.Found 4 files. Please select the driver to download. Additionally, you can choose Operating System to see the drivers that will be compatible with your OS. The Initio INIC-950. BIOS support for DOS and Windows application without driver involvement. TECHNICAL SPECIFICATIONS. OS COMPATABILITY. Lumia 950 driver.

• • • • • • • • Stepper-Bee Twin Stepper Motor Control direct from your PC Animation and robotics made easy Stepper motors are one of the most useful devices in the world of control, automation and robotics. They form the most convenient and versatile bridge between a set of motion rules in a controller (computer) and the motion itself. They can be made to move slowly, quickly, in reverse, pause, complete revolutions, partial revolutions and even individual steps of less than a degree of rotation. With this flexibility of movement coupled with an abundance of torque for relatively little power applied, the stepper motor finds many suitable applications. The downside to stepper motors is that they are not as simple to “drive” (electrically speaking) as simple DC motors, which just need the required volts and amps to do their bit. Stepper motors need a precise sequence of pulses delivered to the correct winding at the correct time in order to perform their required task. It would be nice if all you had to do was specify the number of steps to take, in what direction and at what speed and the stepper motor obliged.

It provides an USB connection for the communication with the PC, it uses a stepper motor that. Operating systems, and. A Linux stepper motor driver module to.

This is the function of the StepperBee USB adaptor board. From the PC these requirements can be specified and “sent” to the StepperBee via USB, which then generates the precise sequence of pulses on the appropriate winding to move the stepper motor accordingly. The StepperBee can accommodate two stepper motors operating completely independently using this technique. For example one stepper motor may be sent off to do 1000 steps clockwise at a rate of 1 step every 100ms followed by 100 steps anti-clockwise at 1 step per minute, whilst at the same time motor 2 can be executing it’s own task which might be to do 100 steps clockwise then anticlockwise in a continuous repeating way at a rate of 1 step/sec.

The StepperBee sorts out the two motors pulse requirements and makes sure both motors are supplied with the correct “drive” to perform the specified tasks. The ability to control two motors with independent tasks in this way opens up many possible application areas for the StepperBee which are not easily available with other stepper motor drives. Popular applications that take advantage of this are with x-y co-ordinate drive systems where one motor controls the X-position and one controls the Y. Specifying the appropriate sequence of tasks can produce some very elaborate positional oriented control systems. Since the StepperBee also has some digital inputs and outputs available for the users program to make use of, it is then possible for these to be used to control a third or 4th axis (albeit in a more simple way) for applications that could, for example, operate a solenoid on the X-Y positioned device. In this way “pick and place” type applications spring to mind. Similarly the StepperBee has a few digital inputs which are typically used to provide some form of feedback from the controlled device.