STEVAL-IHM021V2 STMicroelectronics, STEVAL-IHM021V2 Datasheet - Page 17

STEVAL-IHM021V2

Manufacturer Part Number

STEVAL-IHM021V2

Description

BOARD EVAL L6390/STD5N52U

Manufacturer

STMicroelectronics

Type

Other Power Managementr

Datasheets

1.STD5N52U.pdf (15 pages)

2.L6390DTR.pdf (22 pages)

3.STEVAL-IHM021V2.pdf (5 pages)

Specifications of STEVAL-IHM021V2

Design Resources

STEVAL-IHM021V2 BOM STEVAL-IHM021V2 Schematic

Main Purpose

Power Management, Motor Control

Embedded

Utilized Ic / Part

L6390, STD5N52U

Primary Attributes

3-Ph PMSM, 100 W 3-Phase Inverter, 110 ~ 230VAC

Secondary Attributes

Field-oriented control(FOC) for PMSM

Input Voltage

110 VAC, 230 VAC

Output Voltage

520 V

Operating Supply Voltage

3.3 V, 15 V

Output Power

100 W

Product

Power Management Modules

Lead Free Status / RoHS Status

Lead free / RoHS Compliant

For Use With/related Products

L6390

Other names

497-10543

Current page: 17 of 22
Download datasheet (651Kb)

L6390

9.1

Bootstrap driver

A bootstrap circuitry is needed to supply the high voltage section. This function is normally

accomplished by a high voltage fast recovery diode

integrated structure replaces the external diode. It is realized by a high voltage DMOS,

driven synchronously with the low side driver (LVG), with diode in series, as shown in

8.b. An internal charge pump

To choose the proper C

capacitor. This capacitor C

Equation 1

The ratio between the capacitors C

It has to be:

Equation 2

e.g.: if Q

300 mV.

If HVG has to be supplied for a long time, the C

the leakage and quiescent losses.

e.g.: HVG steady state consumption is lower than 200 μA, so if HVG T

to supply 1 μC to C

The internal bootstrap driver gives a great advantage: the external fast recovery diode can

be avoided (it usually has great leakage current).

This structure can work only if V

LVG is on. The charging time (T

fulfilled and it has to be long enough to charge the capacitor.

The bootstrap driver introduces a voltage drop due to the DMOS R

120 Ω). At low frequency this drop can be neglected. Anyway increasing the frequency it

must be taken in to account.

The following equation is useful to compute the drop on the bootstrap DMOS:

BOOT

gate

selection and charging

is 30 nC and V

EXT

. This charge on a 1 μF capacitor means a voltage drop of 1V.

BOOT

EXT

gate

value the external MOS can be seen as an equivalent

(Figure

Doc ID 14493 Rev 5

is related to the MOS total gate charge:

is 10 V, C

charge

OUT

EXT

is close to GND (or lower) and in the meanwhile the

) of the C

8.b) provides the DMOS driving voltage.

and C

BOOT

EXT

is 3 nF. With C

BOOT

>>> C

BOOT

------------- -

gate

is proportional to the cyclical voltage loss.

EXT

is the time in which both conditions are

(Figure

selection has to take into account also

BOOT

8.a). In the L6390 a patented

= 100 nF the drop would be

DSon

(typical value:

is 5 ms, C

Bootstrap driver

BOOT

Figure

17/22

has

STEVAL-IHM021V2 STMicroelectronics, STEVAL-IHM021V2 Datasheet - Page 17

STEVAL-IHM021V2

Specifications of STEVAL-IHM021V2

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