Features
Part number RDS(on) IOUT VCC
IPS160HF
0.060 Ω
2.4 A
65 V
IPS161HF 0.6A
8 V to 60 V operating voltage range
Minimum output current limitation: 0.7A (IPS161HF) or 2.5A (IPS160HF)
Short propagation delay at start-up
Fast demagnetization of inductive load
Non-dissipative short-circuit protection (cut-off)
Programmable cut-off delay time using external capacitor
Ground disconnection protection
VCC disconnection protection
Thermal shutdown protection
Undervoltage lock-out
Diagnostic signalization for: open load in off-state, cut-off and junction thermal
shutdown
Designed to meet IEC 61131-2
PowerSSO12 package
Applications
Safety applications
Programmable logic control
Industrial PC peripheral input/output
Numerical control machines
Description
The IPS160HF (Iout = 2.4A) and IPS161HF (Iout = 0.6A) are monolithic devices
which can drive capacitive, resistive or inductive loads with one side connected to
ground.
The 60 V operating range and Ron = 60 mΩ, combined with the extended diagnostic
(Open Load, Over Load, Overtemperature) and the < 60 us propagation delay time at
startup (enabling Class 3 for interface types C and D), make the ICs suitable to
address safety applications targeting higher SIL levels.
The built-in overload and thermal shutdown protections guarantee the ICs, the
application and the load against electrical and thermal overstress.
Furthermore, in order to minimize the power dissipation when the output is shorted, a
low-dissipative short-circuit protection (cut-off) is implemented to limit the output
average current value and consequent device overheating.
Cut-off delay time can be set by soldering an external capacitor or disabled by a
resistor on pin 4 (CoD).
The DIAG common diagnostic open drain pin reports the open load in off-state, cut-
off (overload) and thermal shutdown.
Product status
IPS160HF
IPS161HF
Product summary
Order
code
IPS160HF IPS160HFTR
IPS161HF IPS161HFTR
Package PowerSSO12
Packing Tube Tape and reel
Single channel high-side switches
IPS160HF, IPS161HF
Datasheet
DS13271 - Rev 2 - June 2020
For further information contact your local STMicroelectronics sales office.
www.st.com
1Block diagram
Figure 1. Block diagram
IN
GND
Vcc
OUT
CoD
Undervoltage
detection
Vcc clamp
Output clamp
Current limitation
cut -off
Open load in off-state
Junction
Overtemperature
Logic interface
DIAG
GIPG1702151307LM
IPS160HF, IPS161HF
Block diagram
DS13271 - Rev 2 page 2/27
2Pin description
Figure 2. Pin connection (top view)
1
2
3
4
5
6
TAB=Vcc
12
11
10
9
8
7
VCC
IN
DIAG
CoD
NC
NC
OUT
OUT
OUT
OUT
VCC
GND
GIPG1702151321LM
Table 1. Pin configuration
Number Name Function Type
1, 12, TAB VCC Device supply voltage Supply
2 IN Channel input Input
3 DIAG Common diagnostic pin for thermal shutdown, cut-off and open load Output open
drain
4 CoD
Cut-off delay pin, cannot be left floating.
Connected to GND by 1 kΩ resistor to disable the cut-off function. Connect to a CCoD
capacitor to set the cut-off delay see Table 8. Protection and diagnostic
Input
5, 6 NC Not connected
7 GND Device ground Ground
8, 9, 10, 11 OUT Channel power stage output Output
IN This pin drives the output stage to pin OUT. IN pin has internal weak pull-down resistors, see
Table 7. Logic inputs.
OUT Output power transistor is in high-side configuration, with active clamp for fast demagnetization.
DIAG This pin is used for diagnostic purposes and is internally wired to an open drain transistor. The
open drain transistor is turned on in case of junction thermal shutdown, cut-off, or open load in
off-state.
IPS160HF, IPS161HF
Pin description
DS13271 - Rev 2 page 3/27
CoD This pin cannot be left floating and can be used to program the cut-off delay time tcoff, see
Table 8. Protection and diagnostic through an external capacitor (CCoD). The cut-off function
can be completely disabled by connecting the CoD pin to GND through 1 kΩ resistor: in this
condition, the output channel remains in limitation condition, supplying the current to the load
until the input is forced LOW or the thermal shutdown threshold is triggered.
GND IC ground.
The IC can be protected against reverse polarity using two different solutions:
1. Placing a resistor RGND between IC GND pin and load connection point to GND (RGND >
VCC/Icc, see Table 2. Absolute maximum rating). Note that power dissipated by RGND during
reverse polarity condition is Vcc^2/RGND.
2. Placing a diode in parallel to RGND
The diode must be selected such that its VRRM > |VCC| and power dissipation capability is
higher than VF*IS (see Table 4).
In normal operation (no reverse polarity), there is a voltage drop (ΔV) between GND of the
device and GND of the module.
Using option 1, ΔV = RGND * ICC.
Using option 2, ΔV = VF@(IS).
Figure 3. Reverse polarity
VCC IC supply voltage.
IPS160HF, IPS161HF
Pin description
DS13271 - Rev 2 page 4/27
3Absolute maximum ratings
Table 2. Absolute maximum ratings
Symbol Parameter Value Unit
VCC Supply voltage -0.3 to 65 V
VOUT Output channel voltage Vcc-Vclamp to Vcc+0.3 V
IIN Input current -10 to +10 mA
VIN IN voltage VCC V
VCOD Output cut-off voltage pin 5.5 V
ICOD Input current on cut-off pin -1 to +10 mA
VDIAG Fault voltage VCC V
IDIAG Fault current -5 to +10 mA
ICC(1) Maximum DC reverse current flowing through the IC
from GND to VCC -250 mA
IOUT Output stage current Internally limited
A
-IOUT (1) Maximum DC reverse current flowing through the IC
from OUT to VCC 5
EAS (1) Single pulse avalanche energy (TAMB = 125 °C, VCC
= 24 V, Iload = 1 A) 1000 mJ
PTOT Power dissipation at TC = 25 °C (2) Internally limited W
TSTG Storage temperature range -55 to 150
°C
TJJunction temperature -40 to 150
1. Verified on application board with Rth(ja) = 49 °C/W
2. (TJSD(MAX)-TC)/ Rth(JA)
Note: Absolute maximum ratings are the values beyond which damage to the device may occur. Functional operation
under these conditions is not implied. All voltages are referenced to GND.
Table 3. Thermal data
Symbol Parameter Value Unit
Rth(JC) Thermal resistance junction-case 1
°C/W
Rth(JA) Thermal resistance junction-ambient 49
Note: Package mounted on a 2-layer application board with Cu thickness = 35 μm, total dissipation area = 1.5 cm²
connected by 6 vias.
IPS160HF, IPS161HF
Absolute maximum ratings
DS13271 - Rev 2 page 5/27
4Electrical characteristics
(8 V < VCC < 60 V; -40 °C < TJ < 125 °C, unless otherwise specified)
Table 4. Supply
Symbol Parameter Test conditions Min. Typ. Max. Unit
VCC Supply voltage VUVON 60 V
VUVON Undervoltage on threshold 6.9 8 V
VUVOFF Undervoltage off threshold 6.5 7.8 V
VUVH Undervoltage hysteresis 0.15 0.5 V
IS
Supply current in off-state
VCC = 24 V 300 500
μA
VCC = 60 V 350 600
Supply current in on-state
VCC = 24 V 1 1.4
mA
VCC = 60 V 1.4 2.1
ILGND GND disconnection output current VGND = VIN = VCC, VOUT = 0 V 1 mA
Table 5. Output stage
Symbol Parameter Test conditions Min. Typ. Max. Unit
RDS(on) On-state resistance
VCC = 24 V
IOUT =1 A @ TJ = 25 °C 60 80
VCC = 24 V
IOUT =1 A @ TJ = 125 °C 120
VOUT(OFF) Off-state output voltage VIN = 0 V and IOUT = 0 A 2 V
IOUT(OFF) Off-state output current
VCC = 24 V, VIN = 0 V, VOUT = 0 V 3
μA
VCC = 60 V, VIN = 0 V, VOUT = 0 V 10
IOUT(OFF-min) Off-state output current VIN = 0 V, VOUT = 4 V -35 0
Table 6. Switching (VCC = 24 V; -40 °C < TJ < 125 °C, RLOAD = 48 Ω)
Symbol Parameter Test conditions Min. Typ. Max. Unit
trRise time
IOUT = 0.5 A, (see Figure 4. Timing in normal operation )
10
μs
tfFall time 10
tPD(H-L) Propagation delay time off 20
tPD(L-H) Propagation delay time on 30
tD(VCC-ON)
Power-on delay time from
VCC rising edge
IOUT = 0.5 A, (see Figure 5. Propagation delay at start-
up)32 60
IPS160HF, IPS161HF
Electrical characteristics
DS13271 - Rev 2 page 6/27
Figure 4. Timing in normal operation
IPS160HF, IPS161HF
Electrical characteristics
DS13271 - Rev 2 page 7/27
Figure 5. Propagation delay at start-up
VCC
t
t
VOUT
t
td(Vcc-on)
VUVON
10%
VIN
Table 7. Logic inputs
Symbol Parameter Test conditions Min. Typ. Max. Unit
VIL Input low level voltage 0.8
V
VIH Input high level voltage 2.2
VI(HYST) Input hysteresis voltage 0.4
IIN Input current
VCC = VIN = 36 V 200
μA
VCC = VIN = 60 V 550
IPS160HF, IPS161HF
Electrical characteristics
DS13271 - Rev 2 page 8/27
Table 8. Protection and diagnostic
Symbol Parameter Test conditions Min. Typ. Max. Unit
Vclamp VCC active clamp ICC = 10 mA 65.5 68.5 71.5
V
Vdemag Demagnetization voltage IOUT = 0.5 A; load =1 mH VCC-71.5 VCC-68.5 VCC-65.5
VOLoff
Open load (off-state) or short to VCC
detection threshold 2 4
tBKT Open load blanking time 200 μs
VDIAG Voltage drop on DIAG IDIAG = 4 mA 1 V
IDIAG DIAG pin leakage current
VCC ≤ 36 V 110
μA
36 V ˂ VCC ≤ 60 V 180
IPK Output current limitation
activation threshold
IPS161HF
VCC ≤ 24 V, RLOAD ≤ 10 mΩ
1.3 2.1
A
IPS160HF 3.0 4.6
ILIM Output current limitation
IPS161HF 0.7 1.7
IPS160HF 2.5 4.2
tcoff Cut-off current delay time
Programmable by the external
capacitor on CoD pin. Cut-off is
disabled when CoD pin is connected
to GND through 1 kΩ resistor.
TJ˂ TJSD
50xCCOD[nf] ± 35%(1)
μs
tres Output stage restart delay time TJ˂ TJSD 32xtCOFF[μs] ±40%
TJSD Junction temperature shutdown 150 170 190
°C
TJHYST Junction temperature thermal
hysteresis 15
1. The formula is guaranteed in the range 10 nF ≤ CCOD ≤ 100 nF.
IPS160HF, IPS161HF
Electrical characteristics
DS13271 - Rev 2 page 9/27
5Output logic
Table 9. Output stage truth table
Operation IN OUT DIAG
Normal L
H
L
H
H
H
Cut-off L
H
L
L
L
L
Overtemperature L
H
L
L
L
L
Open load L
H
H(1)
H
L (1)
H
UVLO X
X
L
L
X
X
1. External pull-up resistor is used
IPS160HF, IPS161HF
Output logic
DS13271 - Rev 2 page 10/27
6Protection and diagnostic
The IC integrates several protections to ease the design of a robust application.
6.1 Undervoltage lock-out
The device turns off if the supply voltage falls below the turn-off threshold (VUV(off)). Normal operation restarts
after VCC exceeds the turn-on threshold (VUV(on)). Turn-on and turn-off thresholds are defined in Table 4. Supply.
6.2 Overtemperature
The output stage turns off when its internal junction temperature (TJ) exceeds the shutdown threshold TJSD.
Normal operation restarts when TJ comes back below the reset threshold (TJSD - TJHYST), see Table 8. Protection
and diagnostic. The internal fault signal is set when the channel is off due to thermal protection and it is reset
when the junction triggers the reset threshold. This same behavior is signaled on the DIAG pin.
6.3 Cut-off
The IC can limit the output current at the power stage by its embedded output current limitation circuit.
This circuit continuously monitor the output current and, when load is increasing, at the triggering of its activation
threshold (Ipk) it starts limiting to ILIM limitation level: while current limitation is active the IC enters an high
dissipation status.
The IPS160HF implements the cut-off feature which limits the duration of the current limitation condition.
The duration of the current limitation condition (Tcoff) can be set by a capacitor (CCoD) placed between CoD and
GND pins. The design rule for CCoD is:
tcoff[us] ±35% = 50 x Ccod[nF]
The ±35% drift is guaranteed in the range of 10 nF < Ccod < 100 nF; lower capacitance than 10 nF can be used.
If ILIM threshold is triggered, the output stage remains in the current limitation condition (IOUT = ILIM) no longer
than tCOFF. If tCOFF elapses, the output stage turns off and restarts after the tRES restart time.
Thermal shutdown protection has higher priority than cut-off:
IC is forced off if TJSD is triggered before tCOFF elapses
if TJSD is triggered, IC is maintained off even after the tRES has elapsed and until the TJ falls below TJSD-
TJHYST
IPS160HF, IPS161HF
Protection and diagnostic
DS13271 - Rev 2 page 11/27
Figure 6. Current limitation and cut-off
ILIM
tCOFF
~ ~
t
~ ~
IO UT
VI N
t
t
T
J T
J SD
t
VDIAG
tP D( L-H ) tP D( H-L )
~
~
<
The fault condition is reported on the DIAG pin. The internal cut-off flag signal is latched at output switch-off and
released after the time tRES, the same behavior is signaled on DIAG pin.
The status of the DIAG is independent on the IN pin status.
If CoD pin is connected to GND through 1 kΩ resistor (cut-off feature disabled), when the output channel triggers
the limitation threshold, it remains on, in current limitation condition, until the input becomes LOW or the thermal
protection threshold is triggered.
In case of low ambient temperature conditions (TAMB < -20 °C) and high supply voltage (VCC > 36 V), the cut-off
function requires activation in order to avoid damaging the IC.
The following table shows the suggested cut-off delay for different operating voltages.
Table 10. Minimum cut-off delay for TAMB less than -20 °C
VCC [V] Cut-off delay [μs] Cut-off capacitance [nF]
36-48 100 2.2
48-60 50 1
IPS160HF, IPS161HF
Cut-off
DS13271 - Rev 2 page 12/27
6.4 Open load in off-state
The IC provides the open load detection feature which detects if the load is disconnected from the OUT pin. This
feature can be activated by a resistor (RPU) between OUT and VCC pins.
Figure 7. Open load off-state
OUT
PGND
SUPPLY RAIL
GROUND PLANE
Application board
IC
RLOAD
RPU
Open load
detection signal +
-VOLOFF
VCC
VCC
EXPOSED PAD
RLED
RI
In case of wire break and during the OFF state (IN = low), the output voltage VOUT rises according to the
partitioning between the external pull-up resistor and the internal impedance of the IC (130 kΩ < RI < 360 kΩ).
The effect of the LED (if any) on the output pin has to be considered as well. In case of wire break and during the
ON state (IN = high), the output voltage VOUT is pulled up to VCC by the low resistive integrated switch. If the load
is not connected, in order to guarantee the correct open load signalization it must result:
VOUT > VOLoff(max.)
Referring to the circuit in Figure 7. Open load off-state:
VOUT =VCC RPU ×IPU =VCC RPU ×IRI +ILED +IRL (1)
therefore:
RPU <VCC min VOLoff max
VOLoff max
RI min +VOLoff max VLED
RLED
(2)
If the load is connected, in order to avoid any false signalization of the open load, the following condition must
hold:
VOUT < VOLoff(min)
By taking into account the circuit in figure 6:
VOUT =VCC RPU ×IPU =VCC RPU ×VOUT
RI+VOUT VLED
RLED +VOUT
RL(3)
so:
RPU >VCC max VOLoff min
VOLoff min
RI max +VOLoff min VLED
RLED +VOLoff min
RL
(4)
The fault condition is signaled on the DIAG pin and the fault reset occurs when load is reconnected.
If the channel is switched on by the IN pin, the fault condition is no longer detected.
IPS160HF, IPS161HF
Open load in off-state
DS13271 - Rev 2 page 13/27
When an inductive load is driven, some ringing of the output voltage may be observed at the end of the
demagnetization. In fact, the load is completely demagnetized when ILOAD = 0 A and the OUT pin remains floating
until next turn-on. In order to avoid false detection of the open load event when driving inductive loads, the open
load signal is masked for tBKT. So, the open load is reported on the DIAG pin with a delay of tBKT and if the open
load event is triggered for more than tBKT.
6.5 VCC disconnection protection
The IC is protected despite the VCC disconnection event. This event is intended as the disconnection of the VCC
wire from the application board, see figure below. When this condition happens, the IC continues working
normally until the voltage on the VCC pin is ≥ VUVOFF. Once the VUVOFF is triggered, the output channel is turned
off independently on the input status. In case of inductive load, if the VCC is disconnected while the output channel
is still active, the IC allows the discharge of the energy still stored in the inductor through the integrated power
switch.
Figure 8. VCC disconnection
OUT
GND
SUPPLY RAIL
GROUND PLANE
APPLICATION BOARD
IC
VCC
EXPOSED
PAD ON
CVCC
VCC >VUVOFF
DRIVING
CIRCUITRY
IPS160HF, IPS161HF
VCC disconnection protection
DS13271 - Rev 2 page 14/27
6.6 GND disconnection protection
GND disconnection is intended as the disconnection event of the application ground, see figure below. When this
event happens, the IC continues working normally until the voltage between VCC and GND pins of the IC is
≥ VUVOFF. The voltage on GND pin of the IC rises up to the supply rail voltage level. In case of GND
disconnection event, a current (ILGND) flows through OUT pin. Table 4. Supply shows IOUT = ILGND for the worst
case GND disconnection event where the output is shorted to ground.
Figure 9. GND disconnection
OUT
GND
SUPPLY RAIL
GROUND PLANE
APPLICATION BOARD
IC
VCC
EXPOSED
PAD ON
CVCC
VCC
DRIVING
CIRCUITRY
LOAD
IPS160HF, IPS161HF
GND disconnection protection
DS13271 - Rev 2 page 15/27
7Active VDS clamp
Active clamp is also known as fast demagnetization of inductive loads or fast current decay. When a high-side
driver turns off an inductance, an undervoltage is detected on output.
The OUT pin is pulled down to Vdemag. The conduction state is modulated by internal circuitry in order to keep the
OUT pin voltage at about Vdemag until the load energy has been dissipated. The energy is dissipated both in the
IC internal switch and in the load resistance.
Figure 10. Active clamp equivalent principle schematic
OUT
GND
SUPPLY RAIL
GROUND PLANE
APPLICATION BOARD
IC
LLOAD
Clamp
circuitry
VCC
EXPOSED PAD
IPS160HF, IPS161HF
Active VDS clamp
DS13271 - Rev 2 page 16/27
Figure 11. Fast demag waveforms
ILOAD
tDEMAG
IOUT
VIN
t
tON
VOUT
VCC
VCC-VDEMAG
t
t
~~ ~
The demagnetization of inductive load causes large electrical and thermal stress on the IC. The plot below shows
the maximum demagnetization energy that the IC can tolerate in a single demagnetization pulse with VCC = 24 V
and TAMB = 125 °C. If higher demagnetization energy is required, then an external free-wheeling Schottky diode
has to be connected between OUT (cathode) and GND (anode) pins. Note that in this case the fast
demagnetization is inhibited.
IPS160HF, IPS161HF
Active VDS clamp
DS13271 - Rev 2 page 17/27
Figure 12. Typical demagnetization energy (single pulse) at VCC = 24 V and TAMB = 125 °C
0
500
1000
1500
2000
2500
3000
3500
4000
500 700 900 1100 1300 1500 1700 1900 2100 2300 2500
EDEMAG [mJ]
ILOAD [mA]
IPS160HF, IPS161HF
Active VDS clamp
DS13271 - Rev 2 page 18/27
8Package information
In order to meet environmental requirements, ST offers these devices in different grades of ECOPACK packages,
depending on their level of environmental compliance. ECOPACK specifications, grade definitions and product
status are available at: www.st.com. ECOPACK is an ST trademark.
IPS160HF, IPS161HF
Package information
DS13271 - Rev 2 page 19/27
8.1 PowerSSO12 package information
Figure 13. PowerSSO12 package outline
7392413 rev. D
IPS160HF, IPS161HF
PowerSSO12 package information
DS13271 - Rev 2 page 20/27
Table 11. PowerSSO12 package mechanical data
Dim.
mm
Min. Typ. Max.
A1.250 1.700
A1 0.000 0.100
A2 1.100 1.600
B 0.230 0.410
C 0.190 0.250
D 4.800 5.000
E 3.800 4.000
e 0.800
H 5.800 6.200
h 0.250 0.55
L 0.400 1.270
k 0d 8d
X 1.900 2.500
Y 3.600 4.200
ddd 0.100
Note: Dimension D doesn't include mold flash protrusions or gate burrs. Mold flash protrusions or gate burrs don't
exceed 0.15 mm in total both side.
Figure 14. PowerSSO12 recommended footprint
IPS160HF, IPS161HF
PowerSSO12 package information
DS13271 - Rev 2 page 21/27
Figure 15. PowerSSO12 tape packing information [mm]
Figure 16. PowerSS012 reel packing information [mm]
IPS160HF, IPS161HF
PowerSSO12 package information
DS13271 - Rev 2 page 22/27
Revision history
Table 12. Document revision history
Date Revision Changes
23-Apr-2020 1 Initial release.
26-Jun-2020 2 IPS161HF RPN added to document
IPS160HF, IPS161HF
DS13271 - Rev 2 page 23/27
Contents
1Block diagram .....................................................................2
2Pin description ....................................................................3
3Absolute maximum ratings ........................................................5
4Electrical characteristics...........................................................6
5Output logic ......................................................................10
6Protection and diagnostic.........................................................11
6.1 Undervoltage lock-out..........................................................11
6.2 Overtemperature ..............................................................11
6.3 Cut-off.......................................................................11
6.4 Open load in off-state ..........................................................13
6.5 VCC disconnection protection ...................................................14
6.6 GND disconnection protection...................................................15
7Active clamp .....................................................................16
8Package information..............................................................19
8.1 PowerSSO12 package information ...............................................20
Revision history .......................................................................23
IPS160HF, IPS161HF
Contents
DS13271 - Rev 2 page 24/27
List of tables
Table 1. Pin configuration ....................................................................3
Table 2. Absolute maximum ratings .............................................................5
Table 3. Thermal data.......................................................................5
Table 4. Supply ...........................................................................6
Table 5. Output stage .......................................................................6
Table 6. Switching (VCC = 24 V; -40 °C < TJ < 125 °C, RLOAD = 48 Ω)......................................6
Table 7. Logic inputs........................................................................8
Table 8. Protection and diagnostic ..............................................................9
Table 9. Output stage truth table .............................................................. 10
Table 10. Minimum cut-off delay for TAMB less than -20 °C ............................................. 12
Table 11. PowerSSO12 package mechanical data ................................................... 21
Table 12. Document revision history ............................................................. 23
IPS160HF, IPS161HF
List of tables
DS13271 - Rev 2 page 25/27
List of figures
Figure 1. Block diagram ....................................................................2
Figure 2. Pin connection (top view) .............................................................3
Figure 3. Reverse polarity ...................................................................4
Figure 4. Timing in normal operation ...........................................................7
Figure 5. Propagation delay at start-up ..........................................................8
Figure 6. Current limitation and cut-off.......................................................... 12
Figure 7. Open load off-state ................................................................ 13
Figure 8. VCC disconnection ................................................................ 14
Figure 9. GND disconnection ................................................................ 15
Figure 10. Active clamp equivalent principle schematic ............................................... 16
Figure 11. Fast demag waveforms ............................................................. 17
Figure 12. Typical demagnetization energy (single pulse) at VCC = 24 V and TAMB = 125 °C ..................... 18
Figure 13. PowerSSO12 package outline ........................................................ 20
Figure 14. PowerSSO12 recommended footprint ................................................... 21
Figure 15. PowerSSO12 tape packing information [mm] .............................................. 22
Figure 16. PowerSS012 reel packing information [mm] ............................................... 22
IPS160HF, IPS161HF
List of figures
DS13271 - Rev 2 page 26/27
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IPS160HF, IPS161HF
DS13271 - Rev 2 page 27/27