IRF IR1167ASPBF_09

Data Sheet PD60254F
IR1167ASPbF
IR1167BSPbF
SmartRectifierTM CONTROL IC
Features
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Secondary side high speed SR controller
DCM, CrCM and CCM flyback topologies
200V proprietary IC technology
Max 500KHz switching frequency
Anti-bounce logic and UVLO protection
7A peak turn off drive current
Micropower start-up & ultra low quiescent current
10.7/14.5V gate drive clamp
50ns turn-off propagation delay
Vcc range from 11.3V to 20V
Direct sensing of MOSFET drain voltage
Minimal component count
Simple design
Lead-free
Compatible with 1W Standby, Energy Star, CECP, etc.
Description
Package
IR1167S is a smart secondary side driver IC designed to drive N-Channel power MOSFETs
used as synchronous rectifiers in isolated Flyback converters.
The IC can control one or more paralleled N-MOSFETs to emulate the behavior of Schottky
diode rectifiers. 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 continuous, discontinuous
and critical current mode operation and both fixed and variable frequency modes.
8-Lead SOIC
IR1167 Application Diagram
Vin
Rdc
XFM
Cdc
U1
Cs
1
Ci
2
3
RMOT
4
VCC
VGATE
OVT
GND
MOT
VS
EN
VD
IR1167S
Rtn
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8
7
6
Co
LOAD
Rs
5
Rg
Q1
1
IR1167AS/BS
Absolute Maximum Ratings
Stress 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 conditions are not implied. All
voltages are absolute voltages referenced to GND. Thermal resistance and power dissipation are measured
under board mounted and still air conditions.
Parameters
Remarks
Symbol
Min.
Max.
Units
Supply Voltage
VCC
-0.3
20
V
Enable Voltage
VEN
-0.3
20
V
Cont. Drain Sense Voltage
VD
-3
200
V
Pulse Drain Sense Voltage
VD
-5
200
V
Source Sense Voltage
VS
-3
20
V
VGATE
-0.3
20
V
Operating Junction Temperature
TJ
-40
150
°C
Storage Temperature
TS
-55
150
°C
Thermal Resistance
RqJA
128
°C/W
PD
970
mW
SOIC-8, TAMB=25°C
Human Body Model*
Gate Voltage
Package Power Dissipation
ESD Protection
VESD
2
kV
Switching Frequency
fsw
500
kHz
VCC=20V, Gate off
SOIC-8
* Per EIA/JESD22-A114-B( discharging a 100pF capacitor through a 1.5kW series resistor).
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IR1167AS/BS
Electrical Characteristics
The electrical characteristics involve the spread of values guaranteed within the specified supply voltage and
junction temperature range TJ from – 25° C to 125°C. Typical values represent the median values, which are
related to 25°C. If not otherwise stated, a supply voltage of VCC =15V is assumed for test condition.
Supply Section
Parameters
Symbol
Min.
V CC
12
V CC Turn On Threshold
V CC Turn Off Threshold
V CC ON
9.8
(Under Voltage Lock Out)
V CC Turn On/Off Hysteresis
V CC UVLO
V CC HYST
Units
18
V
10.5
11.3
V
8.4
9
9.7
V
1.4
1.55
1.7
V
8.5
10
50
65
10.3
12
IQCC
66
1.8
80
2.2
I CC START
100
200
µA
V CC=V CC
I SLEEP
150
200
µA
V EN=0V, V CC =15V
3.1
3.2
2.15
1.9
2
V
ICC
Operating Current
Quiescent Current
Start-up Current
Sleep Current
Typ.
Remarks
Max.
Supply Voltage Operating Range
Enable Voltage High
V ENHI
2.25
2.15
2.75
Enable Voltage Low
V ENLO
1.3
1.2
1.6
Enable Pull-up Resistance
1.5
REN
GBD
CLOAD=1nF, fsw = 400kHz
IR1167A
C LOAD=10nF, fSW = 400kHz
mA
CLOAD=1nF, fsw = 400kHz
IR1167B
C LOAD=10nF, fSW = 400kHz
mA
ON
- 0.1V
V
MW
GBD
Comparator Section
Parameters
Turn-off Threshold
Symbol
V TH1
Turn-on Threshold
V TH2
Hysteresis
Input Bias Current
V HYST
I IBIAS1
Input Bias Current
I IBIAS2
Min.
Typ.
Max.
-7
-3.5
0
-15
-10.5
-7
-23
-19
-15
-150
-50
55
Remarks
Units
OVT = 0V, V S=0V
mV
OVT floating, V S =0V
OVT = V CC, V S =0V
mV
mV
1
7.5
µA
30
100
µA
2
mV
2
V
Comparator Input Offset
V OFFSET
Input CM Voltage Range
V CM
-0.15
Symbol
Min.
Typ.
Max.
Units
t BLANK
10
9
15
20
25
µs
V D = -50mV
V D = 200V
GBD
One-Shot Section
Parameters
Blanking pulse duration
Reset Threshold
Hysteresis
2.5
V TH3
V HYST3
V
Remarks
V CC=10V - GBD
5.4
V
V CC=20V - GBD
40
mV
V CC=10V - GBD
Minimum On Time Section
Parameters
Minimum on time
Symbol
T ONmin
Remarks
Min.
Typ.
Max.
Units
190
240
290
ns
R MOT =5kW, V CC=12V
2.4
3
3.6
µs
R MOT =75kW, V CC=12V
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IR1167AS/BS
Minimum On Time Section
Parameters
Symbol
TONmin
Minimum on time
Min.
Typ.
Max.
Units
190
240
290
ns
RMOT =5kW, VCC=12V
Remarks
2.4
3
3.6
µs
RMOT =75kW, VCC=12V
Gate Driver Section
Parameters
Gate Low Voltage
Symbol
Min.
VGLO
Typ.
Max.
Units
0.3
0.5
V
Remarks
IGATE = 200mA
Gate High Voltage
VGTH
9.5
9
10.7
12.5
V
IR1167A - VCC=12V-18V (internally clamped)
Gate High Voltage
VGTH
12.5
12
14.5
16.5
V
IR1167B - VCC=12V-18V (internally clamped)
Rise Time
tr1
18
ns
CLOAD = 1nF, VCC=12V
tr2
125
ns
CLOAD = 10nF, VCC=12V
tf1
10
ns
CLOAD = 1nF, VCC=12V
tf2
30
ns
CLOAD = 10nF, VCC=12V
Turn on Propagation Delay
tDon
60
80
ns
VDS to VGATE -100mV overdrive
Turn off Propagation Delay
tDoff
40
65
ns
VDS to VGATE -100mV overdrive
Pull up Resistance
rup
4
W
IGATE = 1A - GBD
rdown
0.7
W
IGATE = -200mA
IO source
2
A
CLOAD = 10nF - GBD
IO sink
7
A
CLOAD = 10nF - GBD
Fall Time
Pull down Resistance
Output Peak Current (source)
Output Peak Current (sink)
**
Guaranteed by Design
STATE AND TRANSITIONS DIAGRAM
POWER ON
Gate Inactive
UVLO MODE
VCC < VCCon
Gate Inactive
ICC max = 200uA
VCC > VCCon
and
ENABLE HIGH
VCC < VCCuvlo
or
ENABLE LOW
NORMAL
Gate Active
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IR1167AS/BS
Block Diagram
MOT
VCC
VCC
UVLO
&
REGULATOR
ENA
VCC
VD
Min ON Time
VTH1
RESET
VS
VGATE
DRIVER
COM
OVT
Min OFF Time
Vgate
RESET
VTH3
VTH2
VTH1
VTH3
VDS
Lead Assignments & Definitions
1
VCC
2
OVT
3
MOT
4
EN
IR1167S
Lead Assignment
Pin#
Symbol
Description
1
VCC
Supply Voltage
2
OVT
Offset Voltage Trimming
3
MOT
Minimum On Time
VGATE
8
GND
7
4
EN
VS
6
5
VD
FET Drain Sensing
6
VS
FET Source Sensing
7
GND
Ground
8
GATE
VD
5
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Enable
Gate Drive Output
5
IR1167AS/BS
Detailed Pin Description
GND: Ground
This is ground potential pin of the integrated control
circuit. The internal devices and gate driver are
referenced to this point.
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 GND.
OVT: Offset Voltage Trimming
The OVT pin will program the amount of input offset
voltage for the turn-off threshold VTH1.
The pin can be optionally tied to ground, to VCC or
left floating, to select 3 ranges of input offset trimming.
This programming feature allows for accomodating
different RDSon MOSFETs.
GATE: 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,
expecially 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.
kelvin contact as close as possible to the power
MOSFET source pin.
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 and or current limiting on this pin is
not recommended as it would limit switching performance of the IC.
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 GND should be
placed as close as possible to the IR1167S.
This pin is internally clamped.
EN: Enable
This pin is used to activate the IC “sleep” mode by
pulling the voltage level below 2.5V (typ). In sleep
mode the IC will consume a minimum amount of current. However all switching functions will be disabled
and the gate will be inactive.
VS: Source Voltage Sense
VS is the differential sense pin for the power MOSFET
Source. This pin must not be connected directly to
the power ground pin (7) but must be used to create a
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IR1167AS/BS
STATES OF OPERATION
GENERAL DESCRIPTION
UVLO/Sleep Mode
The IR1167 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 and guarantee operation in continuous
(CCM), discountinuous (DCM) and critical (CrCM)
conduction 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 < V CC UVLO
occurs.
The sleep mode is initiated by pulling the EN pin below
2.5V (typ). In this mode the IC is essentially shut down
and draws a very low quiescent supply current.
VGate
Normal Mode
The IC enters in normal operating mode once the
UVLO voltage has been exceeded. At this point the
gate driver is operating and the IC will draw a
maximum of ICC from the supply voltage source.
VDS
VTH2
VTH1
VTH3
Input comparator thresholds
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
correspond 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 IR1167 will drive the gate of MOSFET
on which will in turn cause the conduction voltage VDS
to drop down. This drop is usually accompained 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
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IR1167AS/BS
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,
IPRIM
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.
CCM Turn-off phase
In CCM mode the turn off transition is much steeper
and dI/dt involved is much higher. The turn on phase
is identical to DCM or CrCM and therefore won’t be
repeated here.
During the SR FET conduction phase the current will
decay linearly, and so will VDS on the SR FET.
VPRIM
IPRIM
T1
T3
T2
time
VPRIM
ISEC
VSEC
T1
T2
time
ISEC
time
Primary and secondary currents and
voltages for DCM mode
Primary and secondary currents and
voltages for CCM mode
IPRIM
VPRIM
T1
T2
VSEC
time
ISEC
VSEC
time
Once the primary switch will start to turn back on, the
SR FET current will rapidly decrease crossing VTH1
and turning the gate off.
The turn off speed is critical to avoid cross conduction
on the primary side and reduce switching losses.
also in this case a blanking period will be applied, but
given the very fast nature of this transition, it will be
reset as soon as VDS crosses VTH3.
time
Primary and secondary currents and
voltages for CrCM mode
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
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IR1167AS/BS
VTH3
ISEC
V DS
T1
T2
time
VTH1
VTH2
Gate Drive
time
Blanking
time
MOT
Secondary side CCM operation
VTH3
ISEC
VDS
T1
T2
time
VTH1
VTH2
Gate Drive
time
Blanking
MOT
10us blanking
Secondary side DCM/CrCM operation
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IR1167AS/BS
11
VCC UVLO Threshold (V)
ISupply (mA)
10
1
0.1
10
9
VCC ON
VCC UVLO
8
0.01
5
10
15
-50
20
0
50
100
Supply Voltage (V)
Temperature ( °C )
Fig 1. Supply Current vs. Supply Voltage
Fig 2. Under Voltage Lockout
vs. Temp.
0
150
0
VTH2 Threshold (mV)
VTH1 Threshold (mV)
-5
-10
-15
-20
-50
-100
OVT = GND
OVT = Floating
OVT = V CC
-25
-30
-150
-50
0
50
100
150
Temperature ( °C )
Fig 3. VTH1 vs. Temp.
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-50
0
50
100
150
Temperature ( °C )
Fig 4. VTH2 vs. Temp.
10
IR1167AS/BS
0
VTH1 Threshold (mV)
Comparator Hysteresis VHYST (mV)
100
50
-6
VS = -150mV
VS= 0V
VS= +2V
-9
0
-50
0
50
100
-50
150
0
50
100
150
Temperature ( °C )
Temperature ( °C )
Fig 5. Comparator Hysteresis vs.
Temp.
Fig 6. VTH1 vs. Temp. and Common
Mode (OVT=GND)
-50
Comparator Hysteresis (mV)
-50
VTH2 Threshold (mV)
-3
-100
VS = -150mV
VS= 0V
VS= +2V
-100
VS = -150mV
VS= 0V
VS= +2V
-150
-150
-50
0
50
100
150
-50
50
100
150
Temperature ( °C )
Temperature ( °C )
Fig 7. VTH2 vs. Temp. and Common
Mode (OVT=GND)
0
Fig 8. Comparator Hysteresis vs. Temp. and
Common Mode (OVT=GND)
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IR1167AS/BS
100
Input Bias Current (IBIAS2) (µA)
Minimum On Time (µs)
4
3
2
1
RMOT = 5k
RMOT= 75k
80
60
40
TJ = -25°C
TJ = 25°C
20
TJ = 125°C
0
0
-50
0
50
100
150
0
50
Temperature ( °C )
Fig 9. MOT vs. Temp.
Csync = 2nF
Csync = 5nF
Csync = 8nF
Csync = 15nF
Csync = 20nF
19
18
17
16
15
14
13
12
11
150
200
Fig 10. Input Bias Current vs. VD.
20
Maximum Allowable VCC Voltage (V)
Maximum Allowable VCC Voltage (V)
20
100
Drain Sense Voltage (V D) (V)
Csync = 2nF
Csync = 5nF
Csync = 8nF
Csync = 15nF
Csync = 20nF
19
18
17
16
15
14
13
12
11
50
100 150 200 250 300 350 400 450 500
50
100 150 200 250 300 350 400 450 500
Max. Synchronous HEXFET Switching Frequency (kHz)
Max. Synchronous HEXFET Switching Frequency (kHz)
Fig 11. Max. VCC Voltage vs. Synchronous Rectifier
Switching Freq, TJ=125 C, TIC = 85 C, external RG=1W,
1W HEXFET Gate Resistance included
Fig 12. Max. VCC Voltage vs. Synchronous Rectifier
Switching Freq, TJ=125 C, TIC = 85 C, external RG=2W,
1W HEXFET Gate Resistance included
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IR1167AS/BS
Csync = 2nF
Csync = 5nF
Csync = 8nF
Csync = 15nF
Csync = 20nF
19
18
17
16
15
14
13
12
20
Maximum Allowable VCC Voltage (V)
Maximum Allowable VCC Voltage (V)
20
Csync = 2nF
Csync = 5nF
Csync = 8nF
Csync = 15nF
Csync = 20nF
19
18
17
16
15
14
13
12
11
11
50
50
100 150 200 250 300 350 400 450 500
Max. Synchronous HEXFET Switching Frequency (kHz)
Fig 13. Max. VCC Voltage vs. Synchronous Rectifier
Switching Freq, TJ=125 C, TIC = 85 C, external RG=4W,
1W HEXFET Gate Resistance included
100 150 200 250 300 350 400 450 500
Maximum Synchronous HEXFET Switching Frequency (kHz)
Fig 14. Max VCC Voltage vs. Synchronous Rectifier
Switching Freq, TJ=125 C, TIC = 85 C, external RG=6W,
1W HEXFET Gate Resistance included
Figures 11-14 shows the maximum allowable VCC voltage vs. maximum switching frequency for
different loads which are calculated using the design methodology discussed in AN1087.
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IR1167AS/BS
VCC
VCC ON
VCC UVLO
t
UVLO
NORMAL
UVLO
Fig. 14 - Vcc Under Voltage Lockout
VTH1
VDS
V TH2
t Don
t Doff
V Gate
90%
50%
10%
t rise
tfall
Fig. 15 - Timing Diagrams
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IR1167AS/BS
Case outline
D
DIM
B
5
A
FOOTPRINT
6
8
7
6
5
H
E
1
2
3
0.25 [.010]
4
A
6.46 [.255]
6X e
3X 1.27 [.050]
e1
8X b
0.25 [.010]
A1
A
8X 1.78 [.070]
MILLIMETERS
MAX
MIN
.0532
.0688
1.35
1.75
A1 .0040
.0098
0.10
0.25
b
.013
.020
0.33
0.51
c
.0075
.0098
0.19
0.25
D
.189
.1968
4.80
5.00
E
.1497
.1574
3.80
4.00
e
.050 BASIC
1.27 BASIC
e1
A
8X 0.72 [.028]
INCHES
MIN
MAX
.025 BASIC
0.635 BASIC
H
.2284
.2440
5.80
6.20
K
.0099
.0196
0.25
0.50
L
.016
.050
0.40
1.27
y
0°
8°
0°
8°
K x 45°
C
y
0.10 [.004]
8X c
8X L
7
C A B
4. OUTLINE CONFORMS TO JEDEC OUTLINE MS-012AA.
NOTES:
1. DIMENSIONING & TOLERANCING PER ASME Y14.5M-1994.
2. CONTROLLING DIMENSION: MILLIMETER
3. DIMENSIONS ARE SHOWN IN MILLIMETERS [INCHES].
4. OUTLINE CONFORMS TO JEDEC OUTLINE MS-012AA.
5 DIMENSION DOES NOT INCLUDE MOLD PROTRUSIONS.
MOLD PROTRUSIONS NOT TO EXCEED 0.15 [.006].
6 DIMENSION DOES NOT INCLUDE MOLD PROTRUSIONS.
MOLD PROTRUSIONS NOT TO EXCEED 0.25 [.010].
7 DIMENSION IS THE LENGTH OF LEAD FOR SOLDERING TO
A SUBSTRATE.
01-6027
01-0021 11 (MS-012AA)
8-Lead SOIC
Tape and Reel Information (SOIC 8-Lead only)
TERMINAL NUMBER 1
12.3 ( .484 )
11.7 ( .461 )
8.1 ( .318 )
7.9 ( .312 )
FEED DIRECTION
NOTES:
1. CONTROLLING DIMENSION : MILLIMETER.
2. ALL DIMENSIONS ARE SHOWN IN MILLIMETERS(INCHES).
3. OUTLINE CONFORMS TO EIA-481 & EIA-541.
330.00
(12.992)
MAX.
14.40 ( .566 )
12.40 ( .488 )
NOTES :
1. CONTROLLING DIMENSION : MILLIMETER.
2. OUTLINE CONFORMS TO EIA-481 & EIA-541.
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IR1167AS/BS
Part Marking Information
IR1167A
Order Information
8-Lead SOIC IR1167ASPbF
8-Lead SOIC IR1167BSPbF
8-Lead SOIC Tape and Reel IR1167ASTRPbF
8-Lead SOIC Tape and Reel IR1167BSTRPbF
The SOIC-8 is MSL2 qualified
This product has been designed and qualified for the Industrial market.
Data and specifications subject to change without notice.
Qualification Standards can be found at www.irf.com
WORLD HEADQUARTERS: 233 Kansas Street, El Segundo, California 90245 Tel: (310) 252-7105
Data and specifications subject to change without notice. 1/2009
www.irf.com
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