Trinamic TMC603-EVAL evaluation Board TMC603-EVAL 데이터 시트
제품 코드
TMC603-EVAL
TMC603 DATA SHEET (V. 1.05 / 11. Mar. 2009)
27
Copyright © 2008 TRINAMIC Motion Control GmbH & Co. KG
Example:
f
OSC
= 175 kHz, I
OUT
= 0.2 A, V
VM
= 48 V:
For continuous operation, a 330µH or 470µH coil would be required. The minimum inductivity
would be around 100µH.
Note:
Use an inductor, which has a sufficient nominal current rating. Keep switching regulator wiring
away from sensitive signals. When using an open core inductor, please pay special care to not
disturbing sensitive signals.
away from sensitive signals. When using an open core inductor, please pay special care to not
disturbing sensitive signals.
5.5.2
Charge pump
The Villard voltage doubler circuit relies on the switching regulator generating a square wave at the
switching transistor output with a height corresponding to the supply voltage. In order to work properly
the load drawn at +12V needs to be higher than the load drawn at the charge pump voltage. This
normally is satisfied when the IC is supplied by the step down regulator. For low voltage operation, the
charge pump voltage needs to be as high as possible to guarantee a high gate drive voltage, thus, a
dual Schottky diode should be used for the charge pump in low voltage applications.
5.5.3
switching transistor output with a height corresponding to the supply voltage. In order to work properly
the load drawn at +12V needs to be higher than the load drawn at the charge pump voltage. This
normally is satisfied when the IC is supplied by the step down regulator. For low voltage operation, the
charge pump voltage needs to be as high as possible to guarantee a high gate drive voltage, thus, a
dual Schottky diode should be used for the charge pump in low voltage applications.
5.5.3
Supply voltage filtering
As with most integrated circuits, ripple on the supply voltage should be minimized in order to
guarantee a stable operation and to avoid feedback oscillations via the supply voltages. Therefore,
use a ceramic capacitor of 100nF per supply voltage pin (VM to GND, VLS to GND and VCC to GND
and VCP to VM). Please pay attention to also keep voltage ripple on VCC pin low, especially when the
5V output is used to supply additional external circuitry. It also is important to make sure, that the
resistance of the power supply is low when compared to the load circuit. Especially high frequency
voltage ripple >1MHz should be suppressed using filter capacitors near the power bridge or near the
board power supply. The VM terminal is used, to detect short to GND situations, thus, it has to
correspond to the bridge power supply. In high noise applications, it may make sense to filter VCP
supply separately against ripple to GND. A large low ESR electrolytic capacitor across the bridge
supply (VM to GND) should also be used, because it effectively suppresses high frequency ripple. This
cannot be accomplished with ceramic capacitors.
5.5.4
guarantee a stable operation and to avoid feedback oscillations via the supply voltages. Therefore,
use a ceramic capacitor of 100nF per supply voltage pin (VM to GND, VLS to GND and VCC to GND
and VCP to VM). Please pay attention to also keep voltage ripple on VCC pin low, especially when the
5V output is used to supply additional external circuitry. It also is important to make sure, that the
resistance of the power supply is low when compared to the load circuit. Especially high frequency
voltage ripple >1MHz should be suppressed using filter capacitors near the power bridge or near the
board power supply. The VM terminal is used, to detect short to GND situations, thus, it has to
correspond to the bridge power supply. In high noise applications, it may make sense to filter VCP
supply separately against ripple to GND. A large low ESR electrolytic capacitor across the bridge
supply (VM to GND) should also be used, because it effectively suppresses high frequency ripple. This
cannot be accomplished with ceramic capacitors.
5.5.4
Reverse polarity protection
Some applications need to be protected against a reversed biased power supply, i.e. for automotive
applications. A highly efficient reverse polarity protection based on an N channel MOSFET can simply
be added due to the availability of a charge pump voltage. This type of reverse polarity protection
allows feeding back energy into the supply, and thus is preferable to a pure diode reverse polarity
protection.
applications. A highly efficient reverse polarity protection based on an N channel MOSFET can simply
be added due to the availability of a charge pump voltage. This type of reverse polarity protection
allows feeding back energy into the supply, and thus is preferable to a pure diode reverse polarity
protection.
+Terminal
VM
VCP
10k
Reverse polarity power
MOS (i.e. same type as
bridge transistors)
BC846
10k
-Terminal
+V
M
protected
(to bridge)
figure 19: adding a reverse polarity protection
5.5.5
Standby with zero power consumption
In battery powered applications, a standby function often is desired. It allows switching the unit on or
off without the need for a mechanical high power switch. In principle, the bridge driver MOSFETs can
switch off the motor completely, but the TMC603 and its switching regulator still need to be switched
off in order to reduce current consumption to zero. Only a low energy standby power supply will
remain on, in order to wake up the system controller. This standby power supply can be generated by
a low current zener diode plus a resistor to the battery voltage, buffered by a capacitor. The example
in the schematic uses a P channel MOSFET to switch off power for the TMC603 and any additional
off without the need for a mechanical high power switch. In principle, the bridge driver MOSFETs can
switch off the motor completely, but the TMC603 and its switching regulator still need to be switched
off in order to reduce current consumption to zero. Only a low energy standby power supply will
remain on, in order to wake up the system controller. This standby power supply can be generated by
a low current zener diode plus a resistor to the battery voltage, buffered by a capacitor. The example
in the schematic uses a P channel MOSFET to switch off power for the TMC603 and any additional