HIP6601A 查看數據表(PDF) - Intersil
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HIP6601A Datasheet PDF : 11 Pages
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HIP6601A, HIP6603A, HIP6604
be performed to ensure safe operation at the desired
frequency for the selected MOSFETs. The power dissipated
by the driver is approximated as:
P
=
1.05 f s w
3--
2
VU
Q
U
+
VL
QL
+
ID
D
Q
V
CC
where fsw is the switching frequency of the PWM signal. VU
and VL represent the upper and lower gate rail voltage. QU
and QL is the upper and lower gate charge determined by
MOSFET selection and any external capacitance added to
the gate pins. The IDDQ VCC product is the quiescent power
of the driver and is typically 30mW.
The power dissipation approximation is a result of power
transferred to and from the upper and lower gates. But, the
internal bootstrap device also dissipates power on-chip
during the refresh cycle. Expressing this power in terms of
the upper MOSFET total gate charge is explained below.
The bootstrap device conducts when the lower MOSFET or
its body diode conducts and pulls the PHASE node toward
GND. While the bootstrap device conducts, a current path is
formed that refreshes the bootstrap capacitor. Since the
upper gate is driving a MOSFET, the charge removed from
the bootstrap capacitor is equivalent to the total gate charge
of the MOSFET. Therefore, the refresh power required by
the bootstrap capacitor is equivalent to the power used to
charge the gate capacitance of the MOSFET.
PREFRESH
=
1--
2
fSW
QLO
S
S
V
P
V
C
C
=
1--
2
fS
W
QU
V
U
where QLOSS is the total charge removed from the bootstrap
capacitor and provided to the upper gate load.
The 1.05 factor is a correction factor derived from the
following characterization. The base circuit for characterizing
the drivers for different loading profiles and frequencies is
provided. CU and CL are the upper and lower gate load
capacitors. Decoupling capacitors [0.15µF] are added to the
PVCC and VCC pins. The bootstrap capacitor value is
0.01µF.
In Figure 1, CU and CL values are the same and frequency
is varied from 50kHz to 2MHz. PVCC and VCC are tied
together to a +12V supply. Curves do exceed the 800mW
cutoff, but continuous operation above this point is not
recommended.
Figure 2 shows the dissipation in the driver with 3nF loading
on both gates and each individually. Note the higher upper
gate power dissipation which is due to the bootstrap device
refresh cycle. Again PVCC and VCC are tied together and to
a +12V supply.
Test Circuit
+5V OR +12V
+12V
+5V OR +12V
0.01µF
0.15µF
PVCC
VCC
BOOT
UGATE
PHASE
2N7002
CU
0.15µF PWM
LGATE
GND
2N7002
CL
100kΩ
1000
CU = CL = 3nF
800
600
CU = CL = 2nF
400
CU = CL = 1nF
200
CU = CL = 4nF
CU = CL = 5nF
VCC = PVCC = 12V
0
500
1000
1500
2000
FREQUENCY (kHz)
FIGURE 1. POWER DISSIPATION vs FREQUENCY
1000
VCC = PVCC = 12V
800
CU = CL = 3nF
600
400
CU = 3nF
CL = 0nF
CU = 0nF
CL = 3nF
200
0
500
1000
1500
2000
FREQUENCY (kHz)
FIGURE 2. 3nF LOADING PROFILE
The impact of loading on power dissipation is shown in
Figure 3. Frequency is held constant while the gate
capacitors are varied from 1nF to 5nF. VCC and PVCC are
tied together and to a +12V supply. Figures 4 through 6
show the same characterization for the HIP6603A with a
+5V supply on PVCC and VCC tied to a +12V supply.
7
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