IR High Voltage IC
AUIRS1170S
1
2016-09-03
Product Summary
Topology
Flyback, Forward, Half
Bridge
VD
200V
VOUT
10.7 V
IO+ & IO- (typical)
+3/-6A
Turn on propagation
Delay
90ns (typical)
Turn off propagation
Delay
60ns (typical)
Package
PSOP8L
VCC
SYNC
MOT
EN
Vg
Vs
Vd
RMOT
RCC
CVCC
VCC
SYNC
MOT
EN
Vg
Vs
Vd
RMOT
RCC
CVCC
AUIRS1170S AUIRS1170S
Vout
Lo
n:1
GND
Cout
Cf
Rg
Rf
Rg
Cf
Rf
Standard Pack
Base Part Number
Package Type
Form
Quantity
Orderable Part Number
AUIRS1170S
PSOP8L
T&R
2500
AUIRS1170STR
AUIRS1170S
2
Rev. 2.3
2016-09-03
Description
AUIRS1170S is an automotive qualified smart secondary-side driver IC designed to drive N-Channel power
MOSFETs used as synchronous rectifiers in isolated Resonant, Flyback and Forward converters. The IC can
control one or more paralleled Nch-MOSFETs to emulate the behavior of Schottky diode rectifiers.
The AUIRS1170S works in both DCM and CCM operation modes. The SYNC pin should be used in CCM mode
to directly turn-off the MOSFET by a signal from secondary or primary controller. The IC is designed to use simple
capacitor coupling interface with primary controller. In addition to the SYNC control, the drain to source voltage is
sensed differentially to determine the polarity of the current and turn the power switch on and off in proximity of
the zero current transition. Ruggedness and noise immunity are accomplished using an advanced blanking
scheme and double-pulse suppression which allow reliable operation in all operating modes.
The AUIRS1170S is intended for automotive systems that must meet ASIL requirements. In safety critical
applications power devices protection and their status monitoring is an important safety requirement which is
currently addressed with discrete circuitry. The AUIRS1170S includes specific features that simplify and
complement a proper system design, allowing users to achieve up to ASIL-D system rating.
AUIRS1170S
3
Rev. 2.3
2016-09-03
Absolute Maximum Ratings
Absolute Maximum Ratings indicate sustained limits beyond which damage to the device may occur. All voltage
parameters are absolute voltages referenced to Vs lead. Stresses beyond those listed under "
Absolute Maximum Ratings" may cause permanent damage to the device. These are stress ratings only; and
functional operation of the device at these or any other condition beyond those indicated in the “Recommended
Operating Conditions” is not implied. Exposure to absolute-maximum-rated conditions for extended periods may
affect device reliability. The thermal resistance and power dissipation ratings are measured under board mounted
and still air conditions. Ambient temperature (TA) is -40°C≤TA≤125°C, unless otherwise specified.
Recommended Operating Conditions
For proper operation the device should be used within the recommended conditions. All voltage parameters are
absolute voltage referenced to Vs.
Symbol
Definition
Min.
Max.
Units
Remarks
Vcc
Supply voltage
-0.3
20
V
VEN
Enable voltage
-0.3
20
VSYNC
SYNC Voltage
-0.3
20
VGATE
Gate voltage
-0.3
20
Vcc=20V, Gate off
VD
Continuous Drain Sense Voltage
-1
200
VD
Pulse Drain Sense Voltage
-5
200
ISYNC
SYNC Current
-10
10
mA
RthJC
Thermal resistance, junction to case
4
°C/W
PD
Package power dissipation
970
mW
Ta=25C
fSW
Switching frequency
500
kHz
TJ
Operating Junction temperature
-40
150
°C
SOIC-8
TS
Storage temperature
-55
150
SOIC-8, TAMB=25C
TL
Lead temperature (soldering, 10 seconds)
300
Symbol
Definition
Min.
Max.
Units
Vcc
Supply voltage
11
18
V
VD
Drain Sense Voltage
-3
200
TJ
Junction temperature
-25
125
°C
fSW
Switching frequency
---
500
kHz
RMOT
MOT pin resistor value
5
75
k
AUIRS1170S
4
Rev. 2.3
2016-09-03
Static Electrical Characteristics
VCC=15V and -40°C≤TA≤125°C unless otherwise specified. The output voltage and current (Vo and Io)
parameters are referenced to Vs (pin6).
SUPPLY SECTION
COMPARATOR SECTION
Symbol
Definition
Min
Typ
Max
Units
Test Conditions
VCCUV+
Vcc Turn On Threshold
9.4
10.2
11.1
V
VCCUV-
Vcc Turn Off Threshold (UVLO)
8.2
9.3
10.1
VCCHYST
Vcc Turn On/Off Hysteresis
1.7
ICC
Operating Current
45
80
mA
CLOAD=10nF,fSW=400kHz
IQCC
Quiescent Current
1.8
2.4
ICC START
Start-up Current
100
200
A
VCC=VCCUV+ -0.1V
ISLEEP
Sleep Current
150
200
VEN=0V,
VENHI
Enable Voltage High
2.15
2.70
3.4
V
VENLO
Enable Voltage Low
1.2
1.6
2.2
REN
Enable Pull-up Resistance
1.5
M
Symbol
Definition
Min
Typ
Max
Units
Test Conditions
VTH1
Turn-off Threshold
-11
-5
0
mV
Vcc = 18V
VTH2
Turn-on Threshold
-150
-100
-60
Vcc = 18V
VHYST
Hysteresis
90
Vcc = 18V
IIBIAS1
Input Bias Current
45
60
A
VD= - 20mV
Vcc = 18V
Ho = low
AUIRS1170S
5
Rev. 2.3
2016-09-03
ONE SHOT SECTION
* Guaranteed by design
** See MOT Protection Mode section
MINIMUM ON TIME SECTION
*See Pin Description section for RMOT calculation formula
Electrical Characteristics
VCC=15V and -40°C≤TA≤125°C unless otherwise specified. The output voltage and current (VO and IO)
parameters are referenced to Vs (pin6).
SYNC and ENABLE SECTION
(*) guaranteed by design
Symbol
Definition
Min
Typ
Max
Units
Test Conditions
tBLANK
Blanking pulse duration
7.8
17
25
s
VTH3
Reset Threshold
3.9
V
Vcc=15V
VHYST3
Hysteresis *
20
mV
TB
VTH3 reset propagation delay**
400
ns
Symbol
Definition
Min
Typ
Max
Units
Test Conditions
TONmin
Minimum On Time*
100
210
390
ns
RMOT =5k
1.7
2.8
3.9
s
RMOT =75k
Symbol
Definition
Min
Typ
Max
Units
Test Conditions
VSYHI
SYNC Voltage High (disable)
2
2.4
3
V
VSYLO
SYNC Voltage Low (enable)
0.6
0.7
1
V
TSYon
SYNC Turn-on Prop. Delay
90
130
ns
SYNC=high to low
CLOAD=1nF
TSYoff
SYNC Turn-off Prop. Delay
80
120
ns
SYNC=low to high
CLOAD=1nF
TSYPWf
Minimum SYNC Pulse Width(*)
50
ns
Isynch
Synch pin input current
0.8
uA
TdEN_on
Delay from EN high to VG high
20
us
EN_low >6us
TdEN_off
Delay from EN low to VG low (*)
300
ns
AUIRS1170S
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Rev. 2.3
2016-09-03
GATE DRIVER SECTION
(*) guaranteed by design
Symbol
Definition
Min
Typ
Max
Units
Test Conditions
VGLO
Gate Low Voltage
0.19
0.29
V
IGATE=200mA,
Vcc = 12V
VGTH
Gate High Voltage
9.4
10.7
11.9
V
VCC=12V-18V
(internally clamped)
CLOAD=1nF
tr1
Rise Time
70
ns
CLOAD=10nF, VCC=15V
tf1
Fall Time
35
ns
CLOAD=10nF, VCC=15V
TDon
Turn on Propagation Delay
90
120
ns
CLOAD=1nF, VCC=15V
TDoff
Turn off Propagation Delay
60
75
ns
CLOAD=1nF, VCC=15V
IO source
Output Peak Current (source) (*)
3
A
CLOAD=10nF
IO sink
Output Peak Current (sink) (*)
6
A
CLOAD=10nF
AUIRS1170S
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Rev. 2.3
2016-09-03
Functional Block Diagram
AUIRS1170S
8
Rev. 2.3
2016-09-03
Input/Output/Enable Pin Equivalent Circuit Diagrams
AUIRS1170S
9
Rev. 2.3
2016-09-03
Lead Definitions
PIN #
Symbol
Description
1
VCC
Supply Voltage
2
SYNC
SYNC Input for direct turn off
3
MOT
Minimum On Time
4
EN
Enable
5
VD
FET Drain Sensing
6
VS
FET Source Sensing and GND connection
7
NC
Not connected
8
VGATE
Gate Driver Output
ExpPad
at Vs potential, use only for thermal dissipation.
Lead Assignment
Exposed pad
AUIRS1170S
1
2
3
4
8
7
6
5
VCC
SYNC
MOT
EN
VGATE
VS
VD
NC
AUIRS1170S
10
Rev. 2.3
2016-09-03
Detailed Pin Description
VCC: Power Supply
This is the supply voltage pin of the IC and it is monitored by the under voltage lockout circuit. It is possible to turn
off the IC by pulling this pin below the minimum turn off threshold voltage, without damage to the IC.
To prevent noise problems, a bypass ceramic capacitor connected to Vcc and COM should be placed as close as
possible to the AUIRS1170. This pin is internally clamped.
SYNC: Direct Turn-off and Reset
SYNC is used to directly turn-off the SR MOSFET by an external signal. The gate output of AUIRS1170 is low
when SYNC voltage is higher than VSYHI threshold. The propagation delay from SYNC goes high to gate turns off
is 50ns maximum. The turn-off of SYNC is a direct control and it ignores the MOT time (override).
The SYNC pin will reset MOT and Blanking time when SYNC switches from low to high. It will reset MOT timer
and Blanking timer only at the rising edge of signal. This function is useful for very low output voltage condition
(such as overload or short circuit) where the VD voltage is too low to reach Vth3 threshold to reset the timers.
SYNC pin also can be used to control the turn-on time of SR MOSFET (adding additional delay time at turn-on for
noise immunity). If not used, SYNC pin should be connected to COM.
MOT: Minimum On Time
The MOT programming pin controls the amount of minimum on time. Once VTH2 is crossed for the first time, the
gate signal will become active and turn on the power FET. Spurious ringings and oscillations can trigger the input
comparator off. The MOT blanks the input comparator keeping the FET on for a minimum time. The MOT is
programmed between 200ns and 3us (typ.) by using a resistor referenced to COM and can be programmed using
the following formula:
 
EN: Enable
This pin is used to activate the IC “sleep” mode by pulling the voltage level below 1.6V (typ). In sleep mode the IC
will consume a minimum amount of current. All switching functions will be disabled and the gate will be inactive.
VD: Drain Voltage Sense
VD is the voltage sense pin for the power MOSFET Drain. This is a high voltage pin and particular care must be
taken in properly routing the connection to the power MOSFET drain. Additional Filtering is recommended; see
application section for details.
VS: Source Voltage Sense
VS is the differential sense pin for the power MOSFET Source and IC gnd connection. This pin must must be
connected as close as possible to the power MOSFET source pin. Good electrical connection must be done to
this pin since the internal devices and gate driver are referenced to this point.
VGATE: Gate Drive Output
This is the gate drive output of the IC. Drive voltage is internally limited and provides 2A peak source and 7A peak
sink capability. Although this pin can be directly connected to the power MOSFET gate, the use of minimal gate
resistor is recommended, especially when putting multiple FETs in parallel. Care must be taken in order to keep
the gate loop as short and as small as possible in order to achieve optimal switching performance.
AUIRS1170S
11
Rev. 2.3
2016-09-03
Functional Description
State Diagram
UVLO/Sleep Mode
The IC remains in the UVLO condition until the voltage on the VCC pin exceeds the VCC turn on threshold
voltage, VCC ON. During the time the IC remains in the UVLO state, the gate drive circuit is inactive and the IC
draws a quiescent current of ICC START. The UVLO mode is accessible from any other state of operation whenever
the IC supply voltage condition of VCC < VCC UVLO occurs.
The sleep mode is initiated by pulling the EN pin below 1.6V (typ). In this mode the IC is essentially shut down
and draws a very low quiescent supply current.
Normal Mode and Synchronized Enable Function
The IC enters in normal operating mode once the UVLO voltage has been exceeded and the EN voltage is above
VENHI threshold. When the IC enters the Normal Mode from the UVLO Mode, the GATE output is disabled (stays
low) until VDS exceeds VTH3 to activate the gate. This ensures that the GATE output is not enabled in the middle of
a switching cycle. This logic prevents any reverse currents across the device due to the minimum on time function
in the IC. The gate will continuously drive the SR MOSFET after this one-time activation. The Cycle by Cycle
MOT protection circuit is enabled in Normal Mode.
AUIRS1170S
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Rev. 2.3
2016-09-03
MOT Protection Mode
If the secondary current conduction time is shorter than the MOT (Minimum On Time) setting, the next driver
output is disabled. This function can avoid reverse current that occurs when the system works at very low duty-
cycles or at very light/no load conditions and reduce system standby power consumption by disabling GATE
outputs. The Cycle by Cycle MOT Check circuit is always activated under Normal Mode and MOT Protection
Mode, so that the IC can automatically resume normal operation once the load increases to a level and the
secondary current conduction time is longer than MOT.
VG pulse can result shorter than MOT in case the sensed VDS voltage crosses both VTH1 and VTH3 before
MOT time is expired. In particular, VG signal is VTH3 dominant and it is reset when VDS crosses VTH3. Despite
the pulse length may result shorter, the MOT functionality is preserved and AUIRS1170S filters the following VDS
pulse out by keeping VG low. Figure M1 shows the behavior of AUIRS1170S at VG pin in this specific case
(continuous line) and in case VDS does not cross VTH3 before MOT is expired (dotted line).TP represents the
VDS pulse length, TA defines the time at which VDS crosses VTH3, TB is the intrinsic delay of VTH3 reset circuit
and TG is the VG pulse length. TB has been designed in order to filter out possible VDS noises due to switching
of the driven switch and it is in the order of 400ns.
Vth1
Vth3
Vth2
TA TB
Tp
TG
VG
VDS
MOT
Figure M1: VG length as function of VDS in case it crosses VTH3 either
before (continuous line) or after (dotted line) MOT expires.
AUIRS1170S
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Rev. 2.3
2016-09-03
Application Information
General Description
The AUIRS1170 Smart Rectifier IC can emulate the operation of diode rectifier by properly driving a Synchronous
Rectifier (SR) MOSFET. The direction of the rectified current is sensed by the input comparator using the power
MOSFET RDSon as a shunt resistance and the GATE pin of the MOSFET is driven accordingly. Internal blanking
logic is used to prevent spurious transitions. The Synchronous pin (SYNC) can directly take the signal sent from
primary controller to turn off the gate of SR MOSFET prior to the turn-on of primary MOSFET therefore prevent
negative current in SR circuit under CCM condition.
AUIRS1170 is suitable for Flyback, Forward and Resonant Half-Bridge topologies.
Figure 1: Input Comparator Threshold
Flyback Application
The modes of operation for a Flyback circuit differ mainly for the turn-off phase of the SR switch, while the turn-on
phase of the secondary switch (which corresponds to the turn off of the primary side switch) is identical.
Turn-on phase
When the conduction phase of the SR FET is initiated, current will start flowing through its body diode, generating
a negative VDS voltage across it. The body diode has generally a much higher voltage drop than the one caused
by the MOSFET on resistance and therefore will trigger the turn-on threshold VTH2. At that point the AUIRS1170
will drive the gate of MOSFET on which will in turn cause the conduction voltage VDS to drop down. This drop is
usually accompanied by some amount of ringing, that can trigger the input comparator to turn off; hence, a
Minimum On Time (MOT) blanking period is used that will maintain the power MOSFET on for a minimum amount
of time.
The programmed MOT will limit also the minimum duty cycle of the SR MOSFET and, as a consequence, the max
duty cycle of the primary side switch.
DCM/CrCM Turn-off phase
Once the SR MOSFET has been turned on, it will remain on until the rectified current will decay to the level where
VDS will cross the turn-off threshold VTH1. This will happen differently depending on the mode of operation. In DCM
the current will cross the threshold with a relatively low dI/dt. Once the threshold is crossed, the current will start
flowing again through the body diode, causing the VDS voltage to jump negative. Depending on the amount of
residual current, VDS may trigger once again the turn on threshold: for this reason VTH2 is blanked for a certain
amount of time (TBLANK) after VTH1 has been triggered.
The blanking time is internally set. As soon as VDS crosses the positive threshold VTH3 also the blanking time is
terminated and the IC is ready for next conduction cycle.
AUIRS1170S
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Rev. 2.3
2016-09-03
Figure 2: Flyback primary and secondary currents and voltages for DCM mode
Figure 3: Flyback primary and secondary currents and voltages for CrCM mode
Vs
Syn
MOT
EN
NC
Vd
Vcc G
RVcc CVcc
Rg
RMOT
Cout
Cfil
Rfil
Cin
Vin
Rtn
Figure 4: AUIRS1170 in DCM/CrCM mode Flyback
AUIRS1170S
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Rev. 2.3
2016-09-03
Figure 5: AUIRS1170 DCM/CrCM Sync Rect operation (with SYNC connected to COM)
CCM Turn-off phase
In CCM mode the turn on phase is identical to DCM or CrCM and therefore won’t be repeated here. The turn off
transition is much steeper and dI/dt involved is much higher (Figure 6). If the SR controller wait for the primary
switch to turn back on and turn the gate off according to the FET current crossing VTH1, it has high chance to get
reverse current in the SR MOSFET. A predictable turn-off prior to the primary turn-on is necessary. A decoupling
and isolation capacitor can be used to couple the primary gate signal to AUIRS1170 SYNC pin and turn-off the
SR MOSFET prior to the current slope goes to negative. Some turn-on delay to the primary MOSFET can
guarantee no shoot through between the primary and secondary.
In CCM application the connection of AUIRS1170 is recommended as shown in Figure 7.
Figure 6: Primary and secondary currents and voltages for CCM mode
AUIRS1170S
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Rev. 2.3
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Figure 7: AUIRS1170 schematic in CCM mode Flyback
AUIRS1170 is designed to directly take the control information from primary side with capacitor coupling. A high
voltage, low capacitance capacitor is used to send the primary gate driver signal to the SYNC pin. To have the
circuit work properly, a Y cap is required between primary ground and secondary ground. No pulse transformer is
required for the SYNC function, helps saving cost and PCB area.
The turn-off phase with SYNC control is shown in Figure 8.
In this case a blanking period is not applied; SYNC logic high will reset blanking time.
Figure 8: Secondary side CCM operation
AUIRS1170S
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Rev. 2.3
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Forward Application
The typical forward schematic with AUIRS1170 is shown in Figure 9. The operation waveform of SR in Forward is
similar to the CCM operation of Flyback.
Figure 9: Forward application circuit
AUIRS1170S
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Rev. 2.3
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Resonant Half-Bridge Application
The typical application circuit of AUIRS1170 in LLC half-bridge is shown in Figure 10.
Figure 10: Resonant half-bridge application circuit
The SYNC pin can be tied to Vs in LLC converter. The turn-on phase and turn-off phase is similar to flyback
converter except the current shape is sinusoid. The typical operation waveform can be found below.
Figure 11: Resonant half-bridge operation waveforms (SYNC connected to Vs)
AUIRS1170S
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Rev. 2.3
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Application details
Special care has to be taken here in the selection of M3 and M4 mosfets rdson and Qg, because of the current
shape. Being the current sinusoidal, a certain delay is expected from the time the M3 (M4) body diode will start
conducting to the time the M3 (M4) channel will be closed. This depends on the di/dt and on the forward recovery
time of the body diodes. In any case, it is necessary that diode forward voltage rises (in absolute value) above
Vth2 before the gate drive is activated.
Because the forward recovery time of the state of the art mosfets is very short (few tens nsec) and forward
recovery voltage may be several volts, this delay may be neglected, except in case of MHz operation.
So, in absence of any filter on pin Vd, the only significant delay at turn-on is due to the mosfet Qg, charged by the
peak current of the IC gate driver output (3A typ).
On the other side, as deeply discussed in AN1205, some filter is needed on pin Vd, which delays the fall time at
the IC Vd input; for that reason, AN1205 suggests the filter capacitor is quickly discharged trough a diode, whose
anode is connected to pin Vd and whose cathode is connected to the mosfet drain terminal, as shown in fig.12:
Fig.12: Vds filtering of noise generated by layout parasitics
At turn-off, because Vth1 is very low (few mV), very little delay is expected.
As said before, the turn-on delay introduced by the filter on Vd-Vs is deeply discussed in AN1205 and only few
guidelines how to calculate the filter and the relevant delay are given here.
Moreover, an example of estimation of the delay introduced by M3 (M4) rdson and Qg is given.
To such delays, the delay introduced by the Vd-Vs filter has, of course, to be added.
Vds filtering
In resonant and high power applications the synch. rect. switch signal Vds may be not so clean, because of
secondary stray inductances (see an example in figure 13 where dark blue is the voltage across the secondary
switch, called S1; green is the total secondary current, flowing into the two alternate branches of the rectifier, S1
and S2; purple is the primary current and light blue the gate signal of the AUIRS1170S which drives S1).
Except when working at exactly the resonant frequency, there will always be a phase shift between the half (or
full) bridge center tap voltage and the current. This is clearly visible in figure 13, where some extra Vds ringing
appears in the middle of the Vds pulse, caused by the commutation of the primary switches.
This extra ringing on Vds, if not properly filtered, may induce false or premature commutations of the
AUIRS1170S; to be more specific it may happen that at the primary switching transition the induced noise from
primary to secondary forces the turn-off of the active synch. rect Fet. This effect is more evident at low output
current when the signal across the synch. rect Fes is low.
AUIRS1170S
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Rev. 2.3
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Figure 13: practical secondary waveforms in a LLC converter
To improve the noise rejection then a LP filter on Vds is suggested; the general rule is that filter cut-off frequency
has to be set according to the fundamental frequency of the ringings (Fring): because it is a first order filter, its -
3dB frequency shall be at least a decade below the ringing fundamental.
On the other side, the filter introduces delays at both turn-on and turn-off.
An example is shown in figure 14. A filter with a cut-off frequency of 1MHz (100pF - 1.5kOhm ) introduces a turn-
on delay of several hundred nsec (around 650ns).
Fortunately such delay can be easily compensated by introducing a diode in parallel to the filter resistance, which
quickly discharges Cf during the high to low Vds transition.
The effect of such diode is shown in figure 15, where the turn-on delay is now only 134nsec.
Neglecting for a moment the compensation enabled by the diode, the delay cannot become a significant part of
the switching half cycle. The delay introduced by the filter (0 to 90%) is 2.3 * Rf*Cf. Assuming as a starting point
that the delay must stay at least below 20% of the half PWM period (Tsw/2), which is about half of the delay
shown in Fig.14, we have that:
 
  [1]
The delay compensation forced by the diode will then further reduce the real delay, since the discharging
equivalent resistance "Rd" of the diode in forward conduction will be used.
Then the final approximated formula to determine the RC filter pole value is the following:


 

A final verification of the best working value has to be carried on in the real application and a good compromise
has to be found case by case.
AUIRS1170S
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Figure 14: effect of Vds filter on turn-on delay.
Figure 15: diode-discharge compensation of filter induced turn on delay
In all cases, the choice of Rf and Cf is not free. Rf is directly in series with pin Vd on the AUIRS1170S. Because
the input Vd-Vs comparator is fed by an internal current source, adding too much external resistance may
severely impact the turn-on threshold. Therefore a Rf value < 1.5k - 2k Ohm is recommended.
AUIRS1170S
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Rev. 2.3
2016-09-03
Turn-on delay and Mosfet selection
As said, the trigger of Vth2 threshold may be considered instantaneous, because of the forward recovery voltage
of the body diode. After a time Tdon, Vgs will start rising. Because the mosfet is turned-on at zero voltage, there is
no Miller plateau effect. Thus, the time the mosfet channel gets the whole current may be approximated as:
Tdelayon = Tdon + Vgsth*Ciss/IOsource
This delay is almost independent from the secondary current, provided the mosfet has enough transconductance.
A more precise estimation is:
    
󰇛  
 󰇜
Where gm is the mosfet transconductance (at low current levels) and Ipk is the secondary sinusoidal current peak
value.
Worth to say that, to keep the mosfet channel in conduction, the rdson of the mosfet must not be too low!
In fact, if at the expiration of the MOT the channel voltage drop:
Vds = Rdson*i(TONmin) < Vth1
the gate pulse will be immediately terminated and the whole current will go back to the body diode.
A good rule of thumb is then to choose the Mosfet Rdson so that the voltage dropout across it will be around
100mV at max output current.
Turn-off
Turn-off is a bit more critical because, if too long, some cross conduction may occur in the output rectification.
Turn-off will actually be initiated before the current zero crossing, at the time Rdson*i(t) reaches Vth1.
This “anticipation” is given by:
Dt-- = Vth1/(Rdson*2*π*Fsw*Ipk)
After the time Tdoff, due to the IC internal propagation delay, the gate driver will start to discharge the mosfet Qg.
The mosfet channel may be considered fully closed when Vgs approaches Vgsth. Therefore:
Tfall = (Qg-Qgs1)/IOsink
Where Qg is the total gate charge and Qgs1 the gate charge to get to the Vgsth.
The total turn-off delay must then be
Tdelayoff = Tdoff + Tfall < Dt--
This theoretical calculation helps to identify the optimum Rds-on and Qg of the matching synch. rect Fet,
however an experimental verification is always needed to fine tune the application for proper operation.
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Synch functionality in resonant applications
The SYNC pin also can be connected to a control signal for special turn-on and/or turn-off control.
Figure 16 is an example where the SYNC function is used to add some delay to the turn-on phase.
Figure 17 shows instead the use of synch to reset at the end of each cycle when Vds is too low to reach Vth3.
Figure 16: Resonant half-bridge with SYNC control
Figure 17: Reset by SYNC when VD<Vth3
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MOT Protection Mode
The MOT protection prevents reverse current in SR MOSFET. This function works in all three topologies.
Figure 18 is an example in Flyback converter.
Figure 18: MOT Protection Mode
General Timing Waveforms
Figure 19: Timing waveforms
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Suggested pcb layout and footprint
The exposed pad on the bottom side of the package has been introduced to improve the power dissipation
capability of the device. It is weakly electrically connected to the IC substrate, which is at Vs potential.
Therefore, special care has to be taken when designing the board layout.
Figure 20 below show two possible footprints. In both cases, the pad has no pcb traces to any signal. It may be
connected to Vs (pin6), if needed for layout simplification.
Both layout examples use DirectFet™ as synch.rectification devices; as also reported in AN1205, it is important to
have gate connections very similar to each other when several mosfets in parallel are used to carry high currents.
To avoid different Tdon and Tdoff delays due to gate traces inductance.
In the bottom example, the gate connections are optimized from the above point of view.
Figure 20: suggested footprints
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Package Information
PSOP8L
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Qualification Information
Automotive
(per AEC-Q100)
Qualification Level
Comments: This part number passed Automotive qualification.
Industrial and Consumer qualification level is granted by extension of
the higher Automotive level.
Moisture Sensitivity Level
PSOP8L
MSL3
ESD
Human Body Model
Class 1A (500V)*
(AEC-Q100-002, Rev. E)
Charged Device Model
C6 (1000V)
(per AEC-Q100-011, Rev.C)
IC Latch-UP Test
Class II, Level A
(per AEC-Q100-004)
RoHS Compliant
Yes
* Limited by pin 5 (VD), all other pins are rated at 1500V HBM.
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Published by
Infineon Technologies AG
81726 München, Germany
© Infineon Technologies AG 2015
All Rights Reserved.
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