NCP5106A, NCP5106B
www.onsemi.com
16
APPLICATION INFORMATION
Negative Voltage Safe Operating Area
When the driver is used in a half bridge configuration, it
is possible to see negative voltage appearing on the bridge
pin (pin 6) during the power MOSFETs transitions. When
the high−side MOSFET is switched off, the body diode of
the low−side MOSFET starts to conduct. The negative
voltage applied to the bridge pin thus corresponds to the
forward voltage of the body diode. However, as pcb copper
tracks and wire bonding introduce stray elements
(inductance and capacitor), the maximum negative voltage
of the bridge pin will combine the forward voltage and the
oscillations created by the parasitic elements. As any
CMOS device, the deep negative voltage of a selected pin
can inject carriers into the substrate, leading to an erratic
behavior of the concerned component. ON Semiconductor
provides characterization data of its half−bridge driver to
show the maximum negative voltage the driver can safely
operate with. To prevent the negative injection, it is the
designer duty to verify that the amount of negative voltage
pertinent to his/her application does not exceed the
characterization curve we provide, including some safety
margin.
In order to estimate the maximum negative voltage
accepted by the driver, this parameter has been
characterized over full the temperature range of the
component. A test fixture has been developed in which we
purposely negatively bias the bridge pin during the
freewheel period of a buck converter. When the upper gate
voltage shows signs of an erratic behavior, we consider the
limit has been reached.
Figure 51 (or 52), illustrates the negative voltage safe
operating area. Its interpretation is as follows: assume a
negative 10 V pulse featuring a 100 ns width is applied on
the bridge pin, the driver will work correctly over the whole
die temperature range. Should the pulse swing to −20 V,
keeping the same width of 100 ns, the driver will not work
properly or will be damaged for temperatures below
125°C.
Summary:
• If the negative pulse characteristic (negative voltage
level & pulse width) is above the curves the driver
runs in safe operating area.
• If the negative pulse characteristic (negative voltage
level & pulse width) is below one or all curves the
driver will NOT run in safe operating area.
Note, each curve of the Figure 51 (or 52) represents the
negative voltage and width level where the driver starts to
fail at the corresponding die temperature.
If in the application the bridge pin is too close of the safe
operating limit, it is possible to limit the negative voltage
to the bridge pin by inserting one resistor and one diode as
follows:
U1
NCP5106A
VCC
1
IN_HI
2
IN_LO
3
GND
4
DRV_LO
5
BRIDGE
6
DRV_HI
7
VBOOT
8
D1
MUR160
R1
10R
D2
MUR160
C1
100n
M1
M2
Vbulk
0
IN_Hi
IN_LO
0
Vcc
Figure 53. R1 and D1 Improves the Robustness of the
Driver
R1 and D1 should be placed as close as possible of the
driver. D1 should be connected directly between the bridge
pin (pin 6) and the ground pin (pin 4). By this way the
negative voltage applied to the bridge pin will be limited
by D1 and R1 and will prevent any wrong behavior.
ORDERING INFORMATION
Device Package Shipping
†
NCP5106APG PDIP−8 (Pb−Free) 50 Units / Rail
NCP5106ADR2G SOIC−8 (Pb−Free) 2500 / Tape & Reel
NCP5106BPG PDIP−8 (Pb−Free) 50 Units / Rail
NCP5106BDR2G SOIC−8 (Pb−Free) 2500 / Tape & Reel
NCP5106AMNTWG DFN10 (Pb−Free) 4000 / Tape & Reel
NCP5106BMNTWG DFN10 (Pb−Free) 4000 / Tape & Reel
†For information on tape and reel specifications, including part orientation and tape sizes, please refer to our Tape and Reel Packaging
Specifications Brochure, BRD8011/D.
