IRF IR3599

PWM Doubler/Quad Logic
FEATURES
IR3599/IR3599A
DESCRIPTION
 3.3V supply voltage
 Configurable phase multiplier as either
doubler or quad from a single PWM input
 Capable of generating high output
switching frequencies from 200k-800kHz
 Tri-state PWM input and outputs for
power stage shutdown
 IR3599A is configured to accept IR’s
patented Active Tri-Level (ATL) PWM
signals while IR3599 accepts industry’s
standard tri-state PWM signals
 VCC Power-on-reset
 Dual Flat No-Lead (DFN) Package
 Lead free RoHS compliant package
APPLICATIONS
 Servers and Desktop Computers
 High Phase Count and Phase Shedding
Applications
 High Frequency and High Efficiency VRM
IR3599/IR3599A is a phase multiplier which is designed to
double or quadruple the effective maximum phase count
from the controller, enabling a well-controlled, high phase
count voltage regulator.
Each IR3599/IR3599A is able to drive up to four independent
power stages from one PWM input. The IR3599/IR3599A
can be configured as DOUBLER logic where one PWM
signal is internally split to drive the two power stages 180°
out of phase, each at half of the PWM input frequency.
The IR3599/IR3599A can also be configured as QUAD logic
where one PWM signal is internally split at 0º, 90º, 180º,
and 270º respectively, and each at 1/4 of the PWM input
frequency.
IR3599A features the patented IR Active Tri-Level (ATL)
PWM input and output, designed to work with IR digital
multi-phase controller and IR PowIRstage. The unique
doubler/quad mode ATL tri-state timing allows the VR to
transition into tri-state faster during load releases. IR3599
features industry’s standard tri-state PWM input and output
interfaces, designed to work with general multi-phase
controllers, drivers or power stages.
IR3599/IR3599A also incorporates a power-on reset feature,
which ensures the device is active only after the supply
voltage exceeds a certain minimum operating threshold.
ORDERING INFORMATION
Base Part
Number
Package Type
IR3599
Standard Pack
Orderable
Part Number
Form
Quantity
DFN 2 mm x 2 mm
Tape and Reel
3000
IR3599MTRPBF
IR3599A
DFN 2 mm x 2 mm
Tape and Reel
3000
IR3599AMTRPBF
IR3599
DFN 2 mm x 2 mm
Tape and Reel
100
IR3599MTRPBF
IR3599A
DFN 2 mm x 2 mm
Tape and Reel
100
IR3599AMTRPBF
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July 02, 2012 | V1.8
PWM Doubler/Quad Logic
IR3599/IR3599A
ORDERING INFORMATION
IR3599A ―      
IR3599 ―      
PBF – Lead Free
PBF – Lead Free
TR – Tape and Reel
TR – Tape and Reel
M – DFN Package
M – DFN Package
PWM_IN
1
V1p8
2
VCC
3
FUNCTION
4
8
PWM1
GND
7
PWM2
Pad = Pin 9
6
PWM3
5
PWM4
Top View
2x2 DFN
Figure 1: IR3599/IR3599A Package Top View
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July 02, 2012 | V1.8
IR3599/IR3599A
PWM Doubler/Quad Logic
FUNCTIONAL BLOCK DIAGRAM
LDO
VCC
V1p8
POR
PWM_IN
Tri-state
Input Circuit
FUNCTION
PWM1
PWM2
PWM3
PWM4
Tri-state
Output
Circuit
Control
Logic
GND
Figure 2: IR3599/IR3599A Simplified Functional Block Diagram
TABLE 1: FUNCTION CONFIGURATION TABLE
3
Function
PWM Mode
Phase Mode
Part number
0
IR ATL
Quad
IR3599A
1
IR ATL
Doubler
IR3599A
0
Standard Tri-state
Quad
IR3599
1
Standard Tri-state
Doubler
IR3599
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July 02, 2012 | V1.8
PWM Doubler/Quad Logic
IR3599/IR3599A
TYPICAL APPLICATIONS
12V
VIN
PWM
SW
Vout_L1
GND
C
P
U
+3.3V
VIN
VCC
Function
PWM1
PWM2
PWM_IN
PWM3
IR3599A
PWM4
V1P8
PWM4
GND
PWM
SW
GND
VIN
PWM
SW
GND
VIN
RCSP
Rseries
RTh
Rseries
PWM
CCS
RCS
PWM1
ISEN1
IRTN1
RCSM
+3.3V
SW
GND
VCC
IR3565
VSEN
VRTN
RRES
PWM2
ISEN2
IRTN2
TSEN1
VIN
RTh2
PWM
V18A
PWM3
ISEN3
IRTN3
TSEN2
12V RTh3
VINSEN
VRDY1
VRDY2
SVT/SV_ALERT
SV_DIO
SV_CLK
VV
CPU Serial
Bus
VV
VV
Rseries
SW
GND
VIN
PWM
SW
GND
PWM4
ISEN4
IRTN4
VIN
PWM
SW
GND
VDDIO/SV_ADDR
PWM1_L2
ISEN1_L2
IRTN1_L2
SM_DIO
SM_CLK
RCSP_L2
Rseries
RTh
PWM
EN
PWROK/EN_L2/INMODE
VDDIO
Applicable circuit when pin is
configured as VDDIO only
I2C Bus
VIN
VCC
GND
VRHOT_CRIT#
From
System
+3.3V
PWM1
Function
PWM2
PWM_IN
PWM3
IR3599A
PWM4
V1P8
PWM4
RVIN_1
RVIN_2
SW
GND
RCS
+3.3V
VIN
VCC
CCS
Function
RCSM_L2
PWM2_L2
ISEN2_L2
IRTN2_L2
VSEN_L2
VRTN_L2
PWM1
PWM2
PWM_IN
PWM3
IR3599A
PWM4
V1P8
PWM4
GND
PWM
C
P
U
VIN
PWM
SW
GND
ADDR_PROT
GND
Vout_L2
SW
GND
+3.3V
VCC
PWM1
PWM2
PWM_IN
PWM3
IR3599APWM4
V1P8
PWM4
Function
GND
VIN
PWM
SW
GND
VIN
PWM
SW
GND
Figure 3: 20-Phase CPU VR solution using IR3599/A in QUAD mode & PowIRstage with the 6-phase Controller
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July 02, 2012 | V1.8
PWM Doubler/Quad Logic
IR3599/IR3599A
PIN DESCRIPTIONS
PIN #
PIN NAME
1
PWM_IN
2
V1p8
1.8V internal LDO output. Place a high quality low ESR 0.47uF ceramic capacitor from this pin to the
IR3599/IR3599A GND.
3
VCC
Connect this pin to a +3.3V bias supply. Place a high quality low ESR 0.1uF ceramic capacitor from
this pin to the IR3599/IR3599A GND.
4
FUNCTION
The FUNCTION pin controls the Phase Mode (Doubler or Quad Modes). The FUNCTION pin levels
are controlled by connecting the FUNCTION pin to Ground or VCC. Refer to the configuration
instructions in Table 1 to program the FUNCTION pin. At power up, the function pin selection
is latched into the IR3599/IR3599A, and therefore cannot be changed after initial power up.
5
PWM4
Channel 4 PWM signal to the power stage
6
PWM3
Channel 3 PWM signal to the power stage
7
PWM2
Channel 2 PWM signal to the power stage
8
PWM1
Channel 1 PWM signal to the power stage
(PAD) 9
GND
5
PIN DESCRIPTION
The PWM_IN is the control signal input. Connect this pin to the PWM output of the controller. In
Doubler mode, PWM_IN controls the behavior of PWM1 and PWM2. In QUAD mode, PWM_IN
controls the behavior of PWM1, PWM2, PWM3, and PWM4.
Bias and reference ground. All signals are referenced to this node.
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July 02, 2012 | V1.8
PWM Doubler/Quad Logic
IR3599/IR3599A
ABSOLUTE MAXIMUM RATINGS
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 conditions beyond those
indicated in the operational sections of the specifications are not implied.
VCC
-0.3V to +4.0V
PWM_IN, FUNCTION
-0.3V to VCC +0.3V
V1P8
-0.3V to 2.2V
PWMx
-0.3V to VCC +0.3V
ESD
2KV, HBM Class 1-C
Thermal Information
Thermal Resistance (ΘJC)
1
8.9°C/W
Thermal Resistance (ΘJA)
73.2°C/W
Maximum Junction Temperature
150°C
Maximum Storage Temperature Range
-65°C to 150°C
Maximum Lead Temperature (Soldering 10s)
300°C
Note 1: θJA is measured with the component mounted on a high effective thermal conductivity test board in free air.
TBD: To be determined by Design Engineer.
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July 02, 2012 | V1.8
PWM Doubler/Quad Logic
IR3599/IR3599A
ELECTRICAL SPECIFICATIONS
RECOMMENDED OPERATING CONDITIONS FOR RELIABLE OPERATION WITH MARGIN
Recommended Operating Ambient Temperature Range
-40°C to 85°C
Maximum Operating Junction Temperature
125°C
VCC Supply Voltage Range
+2.85V to +3.6V
PWM Output frequency Range
200k-800kHz
ELECTRICAL CHARACTERISTICS
Unless otherwise specified, these specifications were tested at +25°C. VCC = 3.3V.
PARAMETER
SYMBOL
CONDITIONS
MIN
TYP
MAX
UNIT
2.85
3.3
3.6
V
Supply
Supply Voltage
VCC
Supply Bias Current Idle
IVCC_ATL
IR3599A only. PWM_IN floating. Note 1
-
1.07
-
mA
IVCC_TRI
IR3599 only. PWM_IN floating. Note 1
-
1.48
-
mA
IVCC _ATL
IR3599A only. fPWMx = 400kHz, D=10%,
no load.
-
3.04
-
mA
IVCC_TRI
IR3599 only. fPWMx = 400kHz, D=10%,
no load.
-
1.39
-
mA
IVCC _ATL
IR3599A only. fPWMx = 400kHz, D=10%,
no load.
-
4.08
-
mA
IVCC_TRI
IR3599 only. fPWMx = 400kHz, D=10%,
no load.
-
1.38
-
mA
VCC Rising Threshold for POR
-
2.625
-
V
VCC Falling Threshold for POR
-
2.56
-
V
1.67
1.8
1.93
V
Supply Bias Current ― DOUBLER
Mode
Supply Bias Current ― QUAD Mode
LDO Output Voltage
VLDO
VCC=3.3V
PWM Input IR ATL Mode (IR3599A only)
PWM Input High Threshold
VIH(PWM)
-
1.0
-
V
PWM Input Low Threshold
VIL(PWM)
-
0.85
-
V
PWM Tri-level High Threshold
VTH(PWM)
-
2.51
-
V
PWM Tri-level Low Threshold
VTL(PWM)
-
2.36
-
V
PWM Input Current Low
IIL(PWM_ATL)
VPWM = 0V
-
0.92
-
mA
PWM Input Current High
IIH(PWM_ATL)
VPWM = 1.8V
-
0.92
-
mA
-
43
-
ns
Minimum Recognized PWM Pulse
Width
Note 1
PWM Input Standard Tri-state Mode (IR3599 only)
PWM Input High Rising Threshold
VIH(PWM)
-
2.5
-
V
PWM Input High Falling Threshold
VIL(PWM)
-
2.35
-
V
PWM Input Low Rising Threshold
VTH(PWM)
-
1.0
-
V
PWM Input Low Falling Threshold
VTL(PWM)
-
0.85
-
V
PWM Input Current Low
IIL(PWM_TRI)
VPWM = 0V
-
0.35
-
mA
PWM Input Current High
IIH(PWM_TRI)
VPWM = 3.3V
-
0.6
-
mA
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PWM Doubler/Quad Logic
PARAMETER
PWM Input Tri-State Float Voltage
PWM Input Impedance
SYMBOL
VPWM_IN
CONDITIONS
Floating
PWM_IN
= floating
RPWM
Minimum Recognized PWM Pulse
Width
Note 1
IR3599/IR3599A
MIN
TYP
MAX
UNIT
-
1.55 1.4
- 1.5 1.62V
-
4.2
-
kΩ
-
39
-
ns
V
PWM Output (IR3599A only)
PWM Output High Threshold
VOH(PWM)
1.6
-
2.0
V
PWM Output Low Threshold
VOL(PWM)
-
-
0.4
V
Transition Time ― Rise
Transition Time ― Fall
Propagation Delay ― Turn-on
Propagation Delay ― Turn-off
tR(HS)
CPCB=50pF. Measured from 10% to 90%
PWM output. Note 1
-
12.8
-
ns
tF(HS)
CPCB=50pF. Measured from 90% to 10%
PWM output. Note 1
-
7.9
-
ns
tPDH(HS)
Unloaded. Measured from PWM_IN rising
edge to PWM1 rising edge. Note 1
-
15.3
-
ns
tPDL(HS)
Unloaded. Measured from PWM_IN falling
edge to PWM1 falling edge. Note 1
-
9.2
-
ns
tPDTS(en)
Unloaded. Measured from the edge
PWM_IN enters tri-state to PWM1 high
impedance. Note 1
-
10.5
-
ns
tPDTS(dis)
Unloaded. Measured from the edge
PWM_IN exits tri-state to PWM1 high or
low. Note 1
-
24.3
-
ns
Propagation Delay ― Enter Tri-State
Propagation Delay ― Exit Tri-State
Output Impedance ― Source
RHS_SOURCE
-
90
-
Ω
Output Impedance ― Sinking
RHS_SINK
-
57
-
Ω
PWM Output High Threshold
VOH(PWM)
2.85
-
-
V
PWM Output Low Threshold
VOL(PWM)
PWM Output (IR3599 only)
Transition Time ― Rise
Transition Time ― Fall
Propagation Delay ― Turn-on
Propagation Delay ― Turn-off
-
-
0.4
V
tR(HS)
CPCB=50pF. Measured from 10% to 90%
PWM output. Note 1
-
8.4
-
ns
tF(HS)
CPCB=50pF. Measured from 90% to 10%
PWM output. Note 1
-
8.1
-
ns
tPDH(HS)
Unloaded. Measured from PWM_IN rising
edge to PWM1 rising edge. Note 1
-
10.8
-
ns
tPDL(HS)
Unloaded. Measured from PWM_IN falling
edge to PWM1 falling edge. Note 1
-
8.6
-
ns
tPDTS(en)
Loaded with 5kΩ pull-up and 5kΩ pull-down
resistors. Measured from the edge
PWM_IN enters tri-state to PWM1 enters
tri-state. Note 1
-
34.5
-
ns
tPDTS(dis)
Loaded with 5kΩ pull-up and 5kΩ pull-down
resistors. Measured from the edge
PWM_IN exits tri-state to PWM1 high or
low. Note 1
-
23.6
-
ns
RHS_SOURCE
-
55
-
Ω
RHS_SINK
-
45
-
Ω
Propagation Delay ― Enter Tri-State
Propagation Delay ― Exit Tri-State
Output Impedance Source
Output Impedance ― Sinking
Note 1: Guaranteed by design but not tested in production.
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July 02, 2012 | V1.8
IR3599/IR3599A
PWM Doubler/Quad Logic
MODE AND TIMING DIAGRAMS
VCC
FUNCTION
400kHz
PWM_IN
200kHz
PWM1
PWM2
200kHz
Doubler Mode
PWM3
NC
PWM4
NC
800kHz
FUNCTION
PWM_IN
200kHz
PWM1
PWM2
200kHz
Quad Mode
PWM3
PWM4
200kHz
200kHz
Figure 4: IR3599/IR3599A Phase Modes
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July 02, 2012 | V1.8
PWM Doubler/Quad Logic
IR3599/IR3599A
12V
2 Phase Controller
PowIRstage
PWM1
PWMØ1
Doubler
Mode
PWMØ2
Doubler
Mode
PWM2
PWM3
PowIRstage
PowIRstage
PWM4
PowIRstage
PWM
1
PWM
2
PWM1
PWM2
PWM3
PWM4
Figure 5: IR3599A timing when configured in DOUBLER mode (IR ATL PWM signals at input)
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July 02, 2012 | V1.8
PWM Doubler/Quad Logic
IR3599/IR3599A
12V
2 Phase Controller
PowIRstage
PWM1
PWMØ1
Doubler
Mode
PWMØ2
Doubler
Mode
PWM2
PWM3
PowIRstage
PowIRstage
PWM4
PowIRstage
PWM
1
PWM
2
PWM1
PWM2
PWM3
PWM4
Figure 6: IR3599 timing when configured in DOUBLER mode (Industry Standard Tri-state PWM signals at input)
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July 02, 2012 | V1.8
PWM Doubler/Quad Logic
IR3599/IR3599A
12V
2 Phase Controller
PowIRstage
PWMØ1
Quad
Mode
PWM1
PWM2
PWM3
PWM4
PowIRstage
PowIRstage
PowIRstage
PowIRstage
PWMØ2
Quad
Mode
PWM5
PWM6
PWM7
PWM8
PowIRstage
PowIRstage
PowIRstage
PWM 1
PWM 2
PWM1
PWM2
PWM3
PWM4
PWM5
PWM6
PWM7
PWM8
Figure 7: IR3599A timing when configured in Quad mode (IR ATL PWM signals at input)
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July 02, 2012 | V1.8
PWM Doubler/Quad Logic
IR3599/IR3599A
12V
2 Phase Controller
PowIRstage
PWMØ1
Quad
Mode
PWM1
PWM2
PWM3
PWM4
PowIRstage
PowIRstage
PowIRstage
PowIRstage
PWMØ2
Quad
Mode
PWM5
PWM6
PWM7
PWM8
PowIRstage
PowIRstage
PowIRstage
PWM 1
PWM 2
PWM1
PWM2
PWM3
PWM4
PWM5
PWM6
PWM7
PWM8
Figure 8: IR3599 timing when configured in Quad mode (Industry Standard Tri-state PWM signals at input)
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PWM Doubler/Quad Logic
GENERAL DESCRIPTION
IR3599/IR3599A
IR ACTIVE TRI-LEVEL (ATL) PWM
INPUT/OUTPUT SIGNAL
IR3599/IR3599A is a phase multiplier which is
designed for high phase count applications to reduce
the number of interface signals between controller and
drivers. Each IR3599/IR3599A can be configured to
drive up to four independent power stages from one
PWM input. When it is configured in doubler mode,
only two PWM output signals are controlled by the
single PWM input. The doubler logic alternates the
two PWM outputs at half of the PWM input frequency
so that it can generate two out of phase PWM signals.
The rest two PWM output are in tri-state. When it is
configured in quad mode, all four PWM output are
controlled by the single PWM input. The quad logic
will alternate the four PWM outputs at 0º, 90º, 180º,
and 270º respectively, and each at 1/4 of the PWM
input frequency. The phase modes for doubler and
quad are shown in Figure 4.
IR3599A features the patented IR Active Tri-Level
(ATL) PWM input and output, designed to work with
IR digital multi-phase controller and IR PowIRstage.
IR3599 features industry’s standard tri-state PWM
input and output interfaces, designed to work with
general multi-phase controllers, drivers or power
stages.
THEORY OF OPERATION
POWER-ON RESET (POR)
IR3599/IR3599A incorporates a power-on reset
feature, which ensures the device is active only after
the supply voltage is high enough to generate 1.8V.
IR3599/IR3599A is powered from 3.3V DC supply.
An internal LDO generates a 1.8V rail to power the
PWM output in IR3599A. During initial startup,
the 1.8V rail follows the rising 3.3V supply voltage,
proportional to an internal resistor tree. All PWM
outputs are disabled and in a high impedance state
before the VCC supply voltage exceeds the POR
rising threshold.
During normal operation the IR3599/IR3599A
continue to remain active until the VCC supply voltage
falls below the POR falling threshold.
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The IR3599A is driven by a patented active tri-level
(ATL) PWM control signal provided by the IR digital
PWM controllers and also delivers the ATL PWM
signals to the following power stages. During normal
operation, PWM input signal swings between 0V and
1.8V and the generated PWM output signals also
swings between 0 and 1.8V. When PWM input signal
crosses a voltage level higher than the Tri-level high
threshold, it will enter tri-state operation. The IR3599A
provides a 1.0mA typical pull-up current to drive the
PWM input to the tri-state condition of 3.3V when the
PWM controller output is in its high impedance state.
The 1.0mA typical current is designed for driving worst
case stray capacitances and transition the IR3599A
into the tri-state condition rapidly to avoid a prolonged
period of conduction in the following power stage
during faults. This fast tri-state operation eliminates
the need for any tri-state hold-off time of the PWM
signal to dwell in the shutdown window. Immediately
after the IR3599A is driven into the tri-state mode, the
1mA current is disabled so that power is conserved.
Once the IR3599A enters tri-state operation, all of the
PWM outputs will be transitioned to high impedance
states in order to also transition the power stages into
tri-state. This allows the system to operate in single
phase mode when PS2 mode is the mode mode of
operation.
When the PWM input signal level falls below the
tri-level low threshold, the IR3599A will switch back
into normal operation.
INDUSTRY STANDARD TRI-STATE PWM
INPUT/OUTPUT SIGNAL
The IR3599 accepts industry’s standard 3.3V and 5V
tri-state PWM signals. It doubles or quadruples the
single PWM input and then delivers multi-phase PWM
signals to the drivers or power stages. During normal
operation, the PWM input swings from ground to 3.3V
or 5V and the generated PWM output signals will
swing from ground to VCC. If the PWM input is
released from the controller side or if the PWM level is
within a range of 1.65V, the IR3599 will enter tri-state
operation. The floating PWM input will be driven by
the IR3599 to its tri-state window and all the PWM
outputs will also transition to tri-state.
July 02, 2012 | V1.8
PWM Doubler/Quad Logic
IR3599/IR3599A
DOUBLER/QUAD MODE REACTION TO
TRI‐STATE PWM INPUT
In Doubler or quad mode, anytime there is a tri-state
on the PWM_IN, all PWM outputs (PWMx) are tristated immediately with minimum delays. When the
PWM_IN transitions from a tri-state to a high and then
from a high to a low, only the 0 deg phase (PWM1)
operates. This allows the VR to operate properly in
PS2 mode and during load releases. Once the
PWM_IN sees a transition from a low to a high, the
doubler or quad function starts again, with output on
the other PWM pins. The tri-state timing when
configured in doubler mode or quad mode are shown
in Figure 5 - Figure 8.
FREQUENCY RANGE
The IR3599/IR3599A is designed to operate
over a wide input and output frequency range.
When operating in Doubler mode, the input frequency
at the PWM_IN input is 2x the output frequency.
When operating in Quad mode, the input frequency
at the PWM_IN input is 4x the output frequency.
The IR3599/IR3599A is designed to operate with
output frequencies between 200 kHz and 800 kHz.
CONFIGURING THE PHASE MODES
The IR3599/IR3599A can operate in 2 separate
Phase modes which are Doubler and Quad. Table 1
shows the user how to configure the Modes utilizing
the FUNCTION pin. The FUNCTION selection (pin 4)
is latched into the IR3599/IR3599A at power up, and
cannot be changed after power on reset.
SUPPLY DECOUPLING CAPACITOR
VCC decoupling to the IR3599/IR3599A is provided
by a 0.1uF bypass capacitor CVcc located close to the
supply input pin. A series resistor Rvcc, typically 10Ω,
is added in series with the supply voltage to filter high
frequency ringing and noise. A 0.47uF bypass
capacitor located close to V1p8 output pin is
recommended for the internal LDO decouple.
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July 02, 2012 | V1.8
PWM Doubler/Quad Logic
IR3599/IR3599A
ENVIRONMENTAL QUALIFICATIONS
Consumer
Qualification Level
Moisture Sensitivity Level
Machine Model
(JESD22-A115A)
Human Body Model
(JESD22-A114F)
ESD
Charged Device Model
(JESD22-C101D)
“package type”
MSL1
Class B
Maximum MM ESD Voltage ≥ 200V to ≤400V
Class 1C
Maximum HBM ESD Voltage ≥ 2000V to ≤ 4000V
Class III
Maximum CDM ESD Voltage ≥ 500V to ≤1000V
RoHS Compliant
Yes
† Qualification standards can be found at International Rectifier web site: http://www.irf.com
†† Exceptions to AEC-Q101 requirements are noted in the qualification report.
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July 02, 2012 | V1.8
PWM Doubler/Quad Logic
IR3599/IR3599A
MARKING INFORMATION
IR ?
IR ?
Site Code
Site Code
3599A
3599
Date/Lot/Marking Code
Date/Lot/Marking Code
YWLC?
YWLC?
Figure 9: Package Marking
PACKAGE INFORMATION
DFN 2 x 2mm, 8-pin
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July 02, 2012 | V1.8
PWM Doubler/Quad Logic
IR3599/IR3599A
Data and specifications subject to change without notice.
This product will be designed and qualified for the Consumer market.
Qualification Standards can be found on IR’s Web site.
IR WORLD HEADQUARTERS: 233 Kansas St., El Segundo, California 90245, USA Tel: (310) 252-7105
TAC Fax: (310) 252-7903
Visit us at www.irf.com for sales contact information.
www.irf.com
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July 02, 2012 | V1.8