ELECTRICAL CHARACTERISTICS
DYNAMIC ELECTRICAL CHARACTERISTICS
DYNAMIC ELECTRICAL CHARACTERISTICS
Table 5. Dynamic Electrical Characteristics
Characteristics noted under conditions 5.0 V VPWR 28 V, -40 C TA 125 C, GND = 0 V, unless otherwise noted. Typical
values noted reflect the approximate parameter means at TA = 25 °C under nominal conditions, unless otherwise noted.
Symbol
Characteristic
Min
Typ
Max
Unit Notes
TIMING CHARACTERISTICS
f PWM
f MAX
t DON
PWM Frequency
–
Maximum Switching Frequency During Current Limit Regulation
–
Output ON Delay
VPWR = 14 V
–
–
20
kHz
(21)
–
20
kHz
(22)
–
18
s
(23)
t DOFF
tA
tB
t DDISABLE
t F, t R
Output OFF Delay
VPWR = 14 V
ILIM Output Constant-OFF Time
ILIM Blanking Time
Disable Delay Time
Output Rise and Fall Time
SLEW = SLOW
SLEW = FAST
–
–
12
15
20.5
32
12
16.5
27
–
–
8.0
s
(23)
s
(24)
s
(25)
s
(26)
1.5
3.0
6.0
s
(27)
0.2
–
1.45
t FAULT
Short-circuit / Overtemperature Turn-OFF (Latch-OFF) Time
–
–
8.0
s
(28) (29)
t POD
Power-ON Delay Time
–
1.0
5.0
ms
(29)
tRR
Output MOSFET Body Diode Reverse Recovery Time
75
100
150
ns
(29)
fCP
Charge Pump Operating Frequency
–
7.0
–
MHz
(29)
Notes
21. The maximum PWM frequency is obtained when the device is set to Fast Slew Rate via the SLEW pin. PWM-ing when SLEW is set to
SLOW should be limited to frequencies < 11 kHz in order to allow the internal high-side driver circuitry time to fully enhance the high-side
MOSFETs.
22. The internal current limit circuitry produces a constant-OFF-time Pulse Width Modulation of the output current. The output load’s
inductance, capacitance, and resistance characteristics affect the total switching period (OFF-time + ON-time), and thus the PWM
frequency during current limit.
23. Output Delay is the time duration from 1.5 V on the IN1 or IN2 input signal to the 20% or 80% point (dependent on the transition direction)
of the OUT1 or OUT2 signal. If the output is transitioning HIGH-to-LOW, the delay is from 1.5 V on the input signal to the 80% point of
the output response signal. If the output is transitioning LOW-to-HIGH, the delay is from 1.5 V on the input signal to the 20% point of the
output response signal. See Figure 4, page 11.
24. The time during which the internal constant-OFF time PWM current regulation circuit has tri-stated the output bridge.
25. The time during which the current regulation threshold is ignored so that the short-circuit detection threshold comparators may have time
to act.
26. Disable Delay Time measurement is defined in Figure 5, page 11.
27. Rise Time is from the 10% to the 90% level and Fall Time is from the 90% to the 10% level of the output signal with VPWR = 14 V,
RLOAD = 3.0 ohm. See Figure 6, page 11.
28. Load currents ramping up to the current regulation threshold become limited at the ILIM value (see Figure 7). The short-circuit currents
possess a di/dt that ramps up to the ISCH or ISCL threshold during the ILIM blanking time, registering as a short-circuit event detection and
causing the shutdown circuitry to force the output into an immediate tri-state latch-OFF (see Figure 8). Operation in Current Limit mode
may cause junction temperatures to rise. Junction temperatures above ~160C will cause the output current limit threshold to “fold back”,
or decrease, until ~175 C is reached, after which the TLIM thermal latch-OFF will occur. Permissible operation within this fold back region
is limited to non-repetitive transient events of duration not to exceed 30 seconds (see Figure 9).
29. Parameter is guaranteed by design.
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Analog Integrated Circuit Device Data
Freescale Semiconductor