The Instar driver adopts bipolar constant current chopper method to reduce the noise of the stepping motor and make the operation more stable. The increase of the driver power supply voltage greatly improves the driving capability and high-speed performance of the stepping motor. When the stepping pulse stops for more than 100ms, the coil current is automatically halved to reduce the driver heat by 50%.

Instar driver adopts bipolar constant current chopper method to reduce the noise of the stepping motor and make the operation more stable. The increase of the driver power supply voltage greatly improves the driving capability and high-speed performance of the stepping motor. When the stepping pulse stops for more than 100ms, the coil current is automatically halved to reduce the driver heat by 50%.

Instar driver adopts bipolar constant current chopper method to reduce the noise of the stepping motor and make the operation more stable. The increase of the driver power supply voltage greatly improves the driving capability and high-speed performance of the stepping motor. When the stepping pulse stops for more than 100ms, the coil current is automatically halved to reduce the driver heat by 50%.

Instar driver adopts bipolar constant current chopper method to reduce the noise of the stepping motor and make the operation more stable. The increase of the driver power supply voltage greatly improves the driving capability and high-speed performance of the stepping motor. When the stepping pulse stops for more than 100ms, the coil current is automatically halved to reduce the driver heat by 50%.

The Instar driver adopts bipolar constant current chopper method to reduce the noise of the stepping motor and make the operation more stable. The increase of the driver powersupply voltage greatly improves the driving capability and high-speed performance of the stepping motor. When the stepping pulse stops for more than 100ms, the coil current is automatically halved to reduce the driver heat by 50%.

The Instar driver adopts bipolar constant current chopper method to reduce the noise of the stepping motor and make the operation more stable. The increase of the driver power supply voltage greatly improves the driving capability and high-speed performance of the stepping motor. When the stepping pulse stops for more than 100ms, the coil current is automatically halved to reduce the driver heat by 50%.

The Instar driver adopts bipolar constant current chopper method to reduce the noise of the stepping motor and make the operation more stable. The increase of the driver power supply voltage greatly improves the driving capability and high-speed performance of the stepping motor. When the stepping pulse stops for more than 100ms, the coil current is automatically halved to reduce the driver heat by 50%.

The Instar driver adopts bipolar constant current chopper method to reduce the noise of the stepping motor and make the operation more stable. The increase of the driver power supply voltage greatly improves the driving capability and high-speed performance of the stepping motor. When the stepping pulse stops for more than 100ms, the coil current is automatically halved to reduce the driver heat by 50%.

The Instar driver adopts bipolar constant current chopper method to reduce the noise of the stepping motor and make the operation more stable. The increase of the driver powersupply voltage greatly improves the driving capability and highspeed performance of the stepping motor. When the stepping pulse stops for more than 100ms, the coil current is automatically halved to reduce the driver heat by 50%.

Instar driver adopts bipolar constant current chopper method to reduce the noise of the stepping motor and make the operation more stable. The increase of the driver power supply voltage greatly improves the driving capability and high-speed performance of the stepping motor. When the stepping pulse stops for more than 100ms, the coil current is automatically halved to reduce the driver heat by 50%.