Datasheet

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TMC220X, TMC222X DATASHEET (Rev. 1.02 / 2017-MAY-16) 17

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minimized. Therefore, the internal 5V regulator is filtered with a higher capacitance. An optional

resistor bridges the internal 5V regulator by connecting 5VOUT to the external power supply. This RC

filter keeps chopper ripple away from 5VOUT. With this resistor, the external supply is the reference

for the absolute motor current and must not exceed 5.5V.

3.4 Configuration Pins

The TMC22xx family members provide three or four configuration pins depending on the package

option. These pins allow quick configuration for standalone operation. Several additional options can

be set by OTP programming. In UART mode, the configuration pins can be disabled in order to set a

different configuration via registers.

PDN_UART: CONFIGURATION OF STANDSTILL POWER DOWN

PDN_UART

Current Setting

GND

Enable automatic power down in standstill periods

VCC_IO

Disable

UART interface

When using the UART interface, the configuration pin should be disabled via

GCONF.pdn_disable = 1. Program IHOLD as desired for standstill periods.

OPTIONS FOR TMC220X DEVICES, ONLY:

MS1/MS2: CONFIGURATION OF MICROSTEP RESOLUTION FOR STEP INPUT (TMC220X)

MS2

MS1

Microstep Setting

GND

8 microsteps

GND

VCC_IO

2 microsteps (half step)

VCC_IO

GND

4 microsteps (quarter step)

VCC_IO

16 microsteps

OPTIONS FOR TMC222X DEVICES, ONLY:

SPREAD (ONLY WITH TMC222X): SELECTION OF CHOPPER MODE

SPREAD

Chopper Setting

GND or

Pin open / not

available

stealthChop is selected. Automatic switching to spreadCycle in dependence of

the step frequency can be programmed via OTP.

VCC_IO

spreadCycle operation.

MS1/MS2: CONFIGURATION OF MICROSTEP RESOLUTION FOR STEP INPUT (TMC222X)

MS2

MS1

Microstep Setting

GND

4 microsteps (quarter step)

GND

VCC_IO

8 microsteps

VCC_IO

GND

16 microsteps

VCC_IO

32 microsteps

3.5 High Motor Current

When operating at a high motor current, the driver power dissipation due to MOSFET switch on-

resistance significantly heats up the driver. This power dissipation will significantly heat up the PCB

cooling infrastructure, if operated at an increased duty cycle. This in turn leads to a further increase of

driver temperature. An increase of temperature by about 100°C increases MOSFET resistance by

roughly 50%. This is a typical behavior of MOSFET switches. Therefore, under high duty cycle, high

load conditions, thermal characteristics have to be carefully taken into account, especially when

increased environment temperatures are to be supported. Refer the thermal characteristics and the

layout hints for more information. As a thumb rule, thermal properties of the PCB design become