CY525 Datasheet, PDF(96/107 Page) List of Unclassifed Manufacturers

English

English German Russian Spanish Italian Polish Chinese Japanese Korean French Portuguese	Language :

CY525 Datasheet, PDF (96/107 Pages) List of Unclassifed Manufacturers – Stepper System Controller

◁

CY545 Stepper System Controller

www.ControlChips.com

The second basic type of driver circuit is the bipolar design. In this case, the motor is driven only

from the ends of each winding, with switching logic used to control the direction of current

through the winding. These circuits may be implemented with a four lead motor, since only the

ends of each winding are needed.

Bipolar designs are more efficient in driving the motor, and result in higher performance than the

unipolar designs. There is also some gain in torque, since the entire winding is always driven,

unlike the unipolar design, in which only half of a winding is used at a time.

Two methods of switching the direction of current may be used. With a single voltage power

supply, eight transistors are used, two per phase. Transistors are turned on in alternate pairs

across each winding to control the current. The second alternative uses only four transistors, but

requires a dual voltage power supply. In this case, one side of each winding is connected to

ground, and the other side is switched between the positive and negative power supplies. In

both designs it is very important to insure that both transistors on one side of the winding are not

on at the same time, as this would short the power supply through the transistors, generally

destroying the transistors in the process. Protection logic is usually included to insure that one

transistor is off before the other is allowed to turn on.

The most advanced driver designs are variations on the unipolar or bipolar types, although they

are generally implemented using the bipolar approach. These drivers are capable of the highest

step rates attainable. They work by switching current or voltage through the motor at much

higher than the rated value. This is done for only a short period of time, causing the magnetic

field in the motor to change very quickly, without exceeding the maximum power dissipation of

the motor. As long as the average dissipation does not exceed the motor rating, the motor will

perform without problems. Once the maximum limit is reached, the motor may overheat and self

destruct.

One technique for increasing motor performance would simply apply a high voltage to the motor

at the beginning of each step. This makes the motor react very quickly to the change in phase

signals. After a short period of time, the voltage is switched to a lower value, allowing the motor

to continue itâs step without overheating.

A second approach, known as a constant current design, senses the amount of current flowing

through the winding, and adjusts the voltage applied to the motor to maintain the current at its

maximum rated value. At the beginning of a motion, the voltage would be low, with a constant

adjustment to a higher value as the motor speed increases, and back EMF decreases the

current draw for a fixed voltage level.

Chapter 19 - Circuits and Examples

▷