www.power.com May 2018
Up to 8 A Single Channel IGBT/MOSFET Gate Driver
Providing Reinforced Galvanic Isolation
SID11x2K
SCALE-iDriver Family
This Product is Covered by Patents and/or Pending Patent Applications.
Product Highlights
Highly Integrated, Compact Footprint
•Split outputs providing up to 8 A peak drive current
•Integrated FluxLink™ technology providing safe isolation between
primary-side and secondary-side
•Rail-to-rail stabilized output voltage
•Unipolar supply voltage for secondary-side
•Suitable for 600 V / 650 V / 1200 V IGBT and MOSFET switches
•Up to 250 kHz switching frequency
•Low propagation delay time 260 ns
•Propagation delay jitter ±5 ns
•-40 °C to 125 °C operating ambient temperature
•High common-mode transient immunity
•eSOP package with 9.5 mm creepage and clearance
Advanced Protection / Safety Features
•Undervoltage lock-out protection for primary and secondary-side
(UVLO) and fault feedback
•Short-circuit protection using VCESAT monitoring and fault feedback
•Advanced Soft Shut Down (ASSD)
Full Safety and Regulatory Compliance
•100% production partial discharge test
•100% production HIPOT compliance testing at 6 kV RMS 1 s
•Reinforced insulation meets VDE 0884-10
Green Package
•Halogen free and RoHS compliant
Applications
•General purpose and servo drives
•UPS, solar, welding inverters and power supplies
Figure 2. eSOP-R16B Package.
Figure 1. Typical Application Schematic.
Description
The SID11x2K is a single channel IGBT and MOSFET driver in an
eSOP package. Reinforced galvanic isolation is provided by Power
Integrations’ innovative solid insulator FluxLink technology. The up to
8 A peak output drive current enables the product to drive devices up
to 450 A (typical) without requiring any additional active components.
For gate drive requirements that exceed the stand-alone capability of
the SID1182K’s, an external amplier (booster) may be added. Stable
positive and negative voltages for gate control are provided by one
unipolar isolated voltage source.
Additional features such as short-circuit protection (DESAT) with
Advanced Soft Shut Down (ASSD), undervoltage lock-out (UVLO) for
primary-side and secondary-side and rail-to-rail output with tempera-
ture and process compensated output impedance guarantee safe
operation even in harsh conditions.
Controller (PWM and fault) signals are compatible with 5 V CMOS logic,
which may also be adjusted to 15 V levels by using external resistor divider.
Product Portfolio
Product1Peak Output Drive Current
SID1112K 1.0 A
SID1132K 2.5 A
SID1152K 5.0 A
SID1182K 8.0 A
Table 1. SCALE-iDriver Portfolio.
Notes:
1. Package: eSOP-R16B.
PI-7949-072616
IN
SO
VCC
VIN
GND
Fault
Output
VVCC
SCALE-iDriver
Primary-Side
Logic
FluxLink
+
-
VCE
VISO
VGXX
GH
GL
VEE
COM
Secondary-Side
Logic
VTOT
+
-
Rev. G 05/18
2
SID11x2K
www.power.com
Pin Functional Description
VCC Pin (Pin 1):
This pin is the primary-side supply voltage connection.
GND Pin (Pin 3-6):
This pin is the connection for the primary-side ground potential.
All primary-side voltages refer to the pin.
IN Pin (Pin 7):
This pin is the input for the logic command signal.
SO Pin (Pin 8):
This pin is the output for the logic fault signal (open drain).
NC Pin (Pin 9):
This pin must be un-connected. Minimum PCB pad size for soldering
is required.
VEE Pin (Pin 10):
Common (IGBT emitter/MOSFET source) output supply voltage.
VCE Pin (Pin 11):
This pin is the desaturation monitoring voltage input connection.
VGXX Pin (Pin 12):
This pin is the bootstrap and charge pump supply voltage source.
GH Pin (Pin 13):
This pin is the driver output – sourcing current (turn-on) connection.
VISO Pin (Pin 14):
This pin is the input for the secondary-side positive supply voltage.
COM Pin (Pin 15):
This pin provides the secondary-side reference potential.
GL Pin (Pin 16):
This pin is the driver output – sinking current (turn-off).
PI-7648-041415
9 NC
10 VEE
11 VCE
12 VGXX
13 GH
14 VISO
15 COM
16 GLVCC 1
GND 3-6
IN 7
SO 8
Figure 4. Pin Conguration.
Figure 3. Functional Block Diagram.
PI-7654-092216
IN
GND
VEE
COM
GL
GH
VISO
VISO
COM
VDES
VGXX
VCE
SO
VCC
FluxLink
TRANSCEIVER
(BIDIRECTIONAL)
CORE LOGIC
SUPPLY
MONITORING
AUXILIARY
POWER SUPPLIES
CORE LOGIC
SUPPLY
MONITORING
AUXILIARY
POWER SUPPLIES
TRANSCEIVER
(BIDIRECTIONAL)
LEVEL
SHIFTER
ASSD
VEE CONTROL
BOOTSTRAP
CHARGE PUMP
SHORT-CIRCUIT
DETECTION
+
VISO
Rev. G 05/18
3
SID11x2K
www.power.com
SCALE-iDriver Functional Description
The single channel SCALE-iDriver™ family is designed to drive IGBTs
and MOSFETs or other semiconductor power switches with a blocking
voltage of up to 1200 V and provide reinforced isolation between
micro-controller and the power semiconductor switch. The logic
input (PWM) command signals applied via the IN pin and the primary
supply voltage supplied via the VCC pin are both reference to the
GND pin. The working status of the power semiconductor switch and
SCALE-iDriver is monitored via the SO pin.
PMW command signals are transferred from the primary (IN) to
secondary-side via FluxLink isolation technology. The GH pin supplies
a positive gate voltage and charges the semiconductor gate during
the turn-on process. The GL pin supplies the negative voltage and
discharges the gate during the turn-off process.
Short-circuit protection is implemented using a desaturation detection
technique monitored via the VCE pin. After the SCALE-iDriver detects
a short-circuit, the semiconductor turn-off process is implemented
using an Advanced Soft Shut Down (ASSD) technique.
Power Supplies
The SID11x2K requires two power supplies. One is the primary-side
(VVCC) which powers the primary-side logic and communication with
the secondary (insulated) side. One supply voltage is required for the
secondary-side, VTOT is applied between the VISO pin and the COM
pin. VTOT needs to be insulated from the primary-side and must
provide at least the same insulation capabilities as the SCALE-iDriver.
VTOT must have a low capacitive coupling to the primary or any other
secondary-side. The positive gate-emitter voltage is provided by VVISO
which is internally generated and stabilized to 15 V (typically) with
respect to VEE. The negative gate-emitter voltage is provided by VVEE
with respect to COM. Due to the limited current sourcing capabilities
of the VEE pin, any additional load needs to be applied between the
VISO and COM pins. No additional load between VISO and VEE pins
or between VEE and COM pins is allowed.
Input and Fault Logic (Primary-Side)
The input (IN) and output (SO) logic is designed to work directly with
micro-controllers using 5 V CMOS logic. If the physical distance
between the controller and the SCALE-iDriver is large or if a different
logic level is required the resistive divider in Figure 5, or Schmitt-trigger
ICs (Figures 13 and 14) can be used. Both solutions adjust the logic level
as necessary and will also improve the driver’s noise immunity.
Gate driver commands are transferred from the IN pin to the GH and
GL pins with a propagation delay tP(LH) and tP(HL).
During normal operation, when there is no fault detected, the SO pin
stays at high impedance (open). Any fault is reported by connecting
the SO pin to GND. The SO pin stays low as long as the VVCC voltage
(primary-side) stays below UVLOVCC, and the propagation delay is
negligible. If desaturation is detected (there is a short-circuit), or the
supply voltages VVISO, VVEE, (secondary-side) drop below UVLOVISO,
UVLOVEE, the SO status changes with a delay time tFAULT and keeps
status low for a time dened as tSO. In case of a fault condition the
driver applies the off-state (the GL pin is connected to COM). During
the tSO period, command signal transitions from the IN pin are
ignored. A new turn-on command transition is required before the
driver will enter the on-state.
The SO pin current is dened as ISO; voltage during low status is
dened as VSO(FAULT).
Output (Secondary-Side)
The gate of the power semiconductor switch to be driven can be
connected to the SCALE-iDriver output via pins GH and GL, using two
different resistor values. Turn-on gate resistor RGON needs to be
connected to the GH pin and turn-off gate resistor RGOFF to the GL pin.
If both gate resistors have the same value, the GL and GH pins can be
connected together. Note: The SCALE-iDriver data sheet denes the
RGH and RGL values as total resistances connected to the respective
pins GH and GL. Note that most power semiconductor data sheets
specify an internal gate resistor RGINT which is already integrated into
the power semiconductor switch. In Addition to RGINT, external
resistor devices RGON and RGOFF are specied to setup the gate current
levels to the application requirements. Consequently, RGH is the sum
of RGON and RGINT, as shown in Figures 9 and 10. Careful consideration
should be given to the power dissipation and peak current associated
with the external gate resistors.
The GH pin output current source (IGH) of SID1182K is capable of
handling up to 7.3 A during turn-on, and the GL pin output current
source (IGL) is able to sink up to 8.0 A during turn-off. The SCALE-
iDriver’s internal resistances are described as RGHI and RGLI respec-
tively. If the gate resistors for SCALE-iDriver family attempt to draw
a higher peak current, the peak current will be internally limited to a
safe value, see Figures 6 and 7. Figure 8 shows the peak current
Figure 5. Increased Threshold Voltages VIN+LT and VIN+HT
. For R1 = 3.3 kW and
R2 = 1 kW the IN Logic Level is 15 V.
Figure 6. Turn-On Peak Output Current (Source) vs. Ambient Temperature.
Conditions: V
CC
= 5 V, V TOT = 25 V, fS = 20 kHz, Duty Cycle = 50%.
-60 -40 -20 0 20 40 100 120 1408060
Ambient Temperature (°C)
Turn-On Peak Gate Current I
GH (A)
9
8
6
7
5
4
3
2
0
1
PI-7910-121516
RGH = 4 Ω, RGL = 3.4 Ω, CLOAD = 47 nF
RGH = 4 Ω, RGL = 3.4 Ω, CLOAD = 100 nF
RGH = RGL = 0 Ω, CLOAD = 47 nF
PI-7950-050916
SCALE-iDriver
IN
SO
VCC
GND
RSO
R2
R1
C1
Rev. G 05/18
4
SID11x2K
www.power.com
Figure 9. Short-Circuit Protection using a Resistor Chain RVCEX.
Figure 7. Turn-Off Peak Output Current (Sink) vs. Ambient Temperature.
Conditions: V
VCC
= 5 V, V TOT = 25 V, fS = 20 kHz, Duty Cycle = 50%
Figure 8. Turn-On and Turn-Off Peak Output Current vs. Secondary-Side Total
Supply Voltage (VTOT). Conditions: V
VCC
= 5 V, T
J
= 25 °C, R
GH
= 4 W,
R
GL
= 3.4 W, C
LOAD
= 100 nF, f
S
= 1 kHz, Duty Cycle = 50%.
-60 -40 -20 0 20 40 100 120 1408060
Ambient Temperature (°C)
Turn-Off Peak Gate Current I
GL (A)
0
-1
-2
-3
-4
-5
-6
-7
-8
-9
-10
PI-7911-042816
RGH = 4 Ω, RGL = 3.4 Ω, CLOAD = 47 nF
RGH = 4 Ω, RGL = 3.4 Ω, CLOAD = 100 nF
RGH = RGL = 0 Ω, CLOAD = 47 nF
20 21 22 23 24 25 28 29 302726
Secondary-Side Total Supply Voltage – VTOT (V)
Gate Peak Current (A)
7
6
5
4
3
2
1
0
PI-7912-042816
IGH, Turn-On Peak Gate Current
IGL, Turn-Off Peak Gate Current
that can be achieved for a given supply voltage for same gate resistor
values, load capacitance and layout design.
Short-Circuit Protection
The SCALE-iDriver uses the semiconductor desaturation effect to
detect short-circuits and protects the device against damage by
employing an Advanced Soft Shut Down (ASSD) technique. Desatu-
ration can be detected using two different circuits, either with diode
sense circuitry DVCE (Figure 10) or with resistors RVCEX (Figure 9). With
the help of a well stabilized VVISO and a Schottky diode (DSTO) connected
between semiconductor gate and VISO pin the short-circuit current
value can be limited to a safe value.
During the off-state, the VCE pin is internally connected to the COM
pin and CRES is discharged (red curve in Figure 11 represents the
potential of the VCE pin). When the power semiconductor switch
receives a turn-on command, the collector-emitter voltage (VCE)
decreases from the off-state level same as the DC-link voltage to a
normally much lower on-state level (see blue curve in Figure 11) and
CRES begins to be charged up to the VCE saturation level (VCE SAT). CRES
charging time depends on the resistance of RVCEX (Figure 9), DC-link
voltage and CRES and RVCE value. The VCE voltage during on-state is
continuously observed and compared with a reference voltage, VDES.
The VDES level is optimized for IGBT applications. As soon as VCE>VDES
(red circle in Figure 11), the driver turns off the power semiconductor
switch with a controlled collector current slope, limiting the VCE
overvoltage excursions to below the maximum collector-emitter
voltage (VCES). Turn-on commands during this time and during tSO are
ignored, and the SO pin is connected to GND.
The response time tRES is the CRES charging time and describes the
delay between VCE asserting and the voltage on the VCE pin rising
(see Figure 11). Response time should be long enough to avoid false
tripping during semiconductor turn-on and is adjustable via RRES and
CRES (Figure 10) or RVCE and CRES (Figure 9) values. It should not be
longer than the period allowed by the semiconductor manufacturer.
Safe Power-Up and Power-Down
During driver power-up and power-down, several unintended input /
output states may occur. In order to avoid these effects, it is
recommended that the IN pin is kept at logic low during power-up
and power-down. Any supply voltage related to VCC, VISO, VEE and
VGXX pins should be stabilized using ceramic capacitors C1, CS1X, CS2X,
CGXX respectively as shown in Figures 13 and 14. After supply
voltages reach their nominal values, the driver will begin to function
after a time delay tSTART.
Short-Pulse Operation
If command signals applied to the IN pin are shorter than the minimum
specied by tGE(MIN), then SCALE-iDriver output signals, GH and GL
pins, will extend to value tGE(MIN). The duration of pulses longer than
tGE(MIN) will not be changed.
PI-7952-080416
SCALE-iDriver
VCE
VGXX
VISO
GH
RVCEX
RVCE
DSTO
CGXX
RGOFF
Emitter
Collector
RGON
CRES
GL
VEE
COM
Gate RGINT
DCL
Rev. G 05/18
5
SID11x2K
www.power.com
Figure 10. Short-Circuit Protection Using Rectier Diode DVCE.Figure 11. Short-Circuit Protection Using Resistors Chain RVCEX.
PI-7671-093016
V
VCE (IGBT) Signal
VCE Pin Signal
VDES
VCE SAT
tRES t
Fault
COM
Advanced Soft Shut Down (ASSD)
This function is activated after a short-circuit is detected. It protects
the power semiconductor switch against destruction by ending the
turn-on state and limiting the current slope in order to keep momen-
tary VCE overvoltages below VCES. This function is particularly suited to
IGBT applications. Figure 12 shows how the ASSD function operates.
The VCE desaturation is visible during time period P1 (yellow line).
During this time, the gate-emitter voltage (green line) is kept very
stable. Collector current (pink line) is also well stabilized and limited
Figure 12. Advanced Soft Shut Down Function.
to a safe value. At the end of period P1, VGE is reduced during tFSSD1.
Due to collector current decrease a small VCE overvoltage is seen.
During tFSSD1 VGE is further reduced and the gate of the power
semiconductor switch is further discharged. During tFSSD2 additional
small VCE overvoltage events may occur. Once VGE drops below the
gate threshold of the IGBT, the collector current has decayed almost to
zero and the remaining gate charge is removed ‒ ending the short-
circuit event. The whole short-circuit current detection and safe
switch-off is lower than 10 µs (8 µs in this example).
ICE
VGE
VCE
IGE
P1
tFSSD1
tFSSD2
PI-7951-080416
VCE
VGXX
VISO
GH
RRES
RVCE
DSTO
CGXX
RGOFF
DVCE
Emitter
Collector
RGON
CRES
GL
VEE
COM
SCALE-iDriver
Gate RGINT
Rev. G 05/18
6
SID11x2K
www.power.com
Figure 13. SCALE-iDriver Application Example Using a Resistor Network for Desaturation Detection.
Figure 14. SCALE-iDriver Application Example Using Diodes for Desaturation Detection.
Application Examples and Components Selection
Figures 13 and 14 show the schematic and typical components used
for a SCALE-iDriver design. In both cases the primary-side supply
voltage (VVCC) is connected between VCC and GND pins and supported
through a supply bypass ceramic capacitor C1 (4.7 µF typically). If the
command signal voltage level is higher than the rated IN pin voltage
(in this case 15 V) a resistive voltage divider should be used. Additional
capacitor CF and Schmitt trigger IC1 can be used to provide input
signal ltering. The SO output has 5 V logic and the RSO is selected
so that it does not exceed absolute maximum rated ISO current.
The secondary-side isolated power supply (VTOT) is connected between
VISO and COM. The positive voltage rail (VVISO) is supported through
4.7 µF ceramic capacitors CS21 and CS22 connected in parallel. The
negative voltage rail (VVEE) is similarly supported through capacitors
CS11 and CS12. The gate charge will vary according to the type of
power semiconductor switch that is being driven. Typically, CS11 + CS12
should be at least 3 µF multiplied by the total gate charge of the
power semiconductor switch (QGATE) divided by 1 µC. A 10 nF capacitor
CGXX is connected between the GH and VGXX pins.
The gate of the power semiconductor switch is connected through
resistor RGON to the GH pin and by RGOFF to the GL pin. If the value of
RGON is the same as RGOFF the GH pin can be connected to the GL pin
and a common gate resistor can be connected to the gate. In each
case, proper consideration needs to be given to the power dissipation
and temperature performance of the gate resistors.
To ensure gate voltage stabilization and collector current limitation
during a short-circuit, the gate is connected to the VISO pin through
a Schottky diode DSTO (for example PMEG4010).
PI-7953-092216
CGXX
10 nF
CS21
4.7 µF
CS22
4.7 µF
CS11
4.7 µF
CS12
4.7 µF
RGON
RGOFF
RVCE
330 ΩDVCE2 DVCE1
CRES
33-330 pF
RGE
6.8 kΩ
RRES
24-62 kΩ
Gate
Emitter
Collector
IN
SO
VCC
GND
CF
SO
RSO
4.7 kΩ
R2
1 kΩ
R1
3.3 kΩ
VCC
GND
IC1
74LVC
C1
4.7 µF
Command
Signal
DSTO
SCALE-iDriver
Primary-Side
Logic
Secondary-Side
Logic
VCE
VISO
VGXX
GH
GL
VEE
COM
VTOT
+
-
FluxLink
Primary-Side
Logic
IN
SO
VCC
GND
CF
SO
RSO
4.7 kΩ
R2
1 kΩ
R1
3.3 kΩ
VCC
GND
C1
4.7 µF
Command
Signal
DCL
BAS416
PI-7954-092216
CGXX
10 nF
CS21
4.7 µF
CS22
4.7 µF
CS11
4.7 µF
CS12
4.7 µF
RGON
RGOFF
RVCE2-11
100 kΩ × 10
CRES
33 pF
RGE
6.8 kΩ
Gate
Emitter
Collector
DSTO
SCALE-iDriver
Primary-Side
Logic
Secondary-Side
Logic
RVCE
120 kΩ
VCE
VISO
VGXX
GH
GL
VEE
COM
VTOT
+
-
FluxLink
IC1
74LVC
Rev. G 05/18
7
SID11x2K
www.power.com
To avoid parasitic power-switch-conduction during system power-on,
the gate is connected to COM through 6.8 kW resistor.
Figure 13 shows how switch desaturation can be measured using
resistors RVCE2 – RVCE11. In this example all the resistors have a value
of 100 kW and 1206 size. The total resistance is 1 MW. The resistors
should be chosen to limit current to between 0.6 mA to 0.8 mA at
maximum DC-link voltage. The sum of RVCE2 – RVCE11 should be
approximately 1 MW for 1200 V semiconductors and 500 kW for 600 V
semiconductors. In each case the resistor string must provide
sufcient creepage and clearance distances between collector of the
semiconductor and SCALE-iDriver. The low leakage diode DCL keeps
the short-circuit duration constant over a wide DC-link voltage range.
Response time is set up through RVCE and CRES (typically 120 kW and
33 pF respectively for 1200 V semiconductors). If short-circuit
detection proves to be too sensitive, the CRES value can be increased.
The maximum short-circuit duration must be limited to the maximum
value given in the semiconductor data sheet.
Figure 14 illustrates how diodes DVCE1 and DVCE2 may be used to
measure switch desaturation. For insulation, two diodes in SMD
packages are used (STTH212U for example). RRES connected to VISO
guarantees current ow through the diodes when the semiconductor
is in the on-state. When the switch desaturates, CRES starts to be
charged through RRES. In this conguration the response time is
controlled by RRES and CRES. In this application example CRES = 33 pF
and RRES = 62 kW; if desaturation is too sensitive or the short-circuit
duration too long, both CRES and RRES can be adjusted.
Figure 15 shows the recommended PCB layout and corresponds to
the schematic in Figure 13. The PCB is a two layer design. It is
important to ensure that PCB traces do not cover the area below the
desaturation resistors or diodes DVCE1 and DVCE2. This is a critical
design requirement to avoid coupling capacitance with the SCALE-
iDriver’s VCE pin and isolation issues within the PCB.
Gate resistors are located physically close to the power semiconductor
switch. As these components can get hot, it is recommended that
they are placed away from the SCALE-iDriver.
Power Dissipation and IC Junction
Temperature Estimation
First calculation in designing the power semiconductor switch gate
driver stage is to calculate the required gate power - PDRV. The power
is calculated based on equation 1:
PQ fV
DRV GATES TOT
##=
(1)
where,
QGATE – Controlled power semiconductor switch gate charge (derived
for the particular gate potential range dened by VTOT). See semicon-
ductor manufacturer data sheet.
ƒS – Switching frequency which is same as applied to the IN pin of
SCALE-iDriver.
VTOT – SCALE-iDriver secondary-side supply voltage.
In addition to PDRV, PP (primary-side IC power dissipation) and PSNL
(secondary-side IC power dissipation without capacitive load) must be
considered. Both are ambient temperature and switching frequency
dependent (see typical performance characteristics).
PV I
VCCVCCP#=
(2)
PVI
TO
TV
ISOSNL
#=
(3)
During IC operation, the PDRV power is shared between turn-on (RGH),
turn-off (RGL) external gate resistors and internal driver resistances
RGHI and RGLI. For junction temperature estimation purposes, the
dissipated power under load (POL) inside the IC can be calculated
accordingly to equation 4:
.VRR
R
RR
R
PQf05
OL GATE STOT
GHIGH
GHI
GHLGL
GHL
####=+++
bl
(4)
RGH and RGL represent sum of external (RGON, RGOFF) and power
semiconductor internal gate resistance (RGINT):
RR R
RR R
GH GO
NG
INT
GL GOFF GINT
=+
=+
Total IC power dissipation (PDIS) is estimated as sum of equations 2, 3
and 4:
PP
PP
DI
SO
LPSNL
=+ + (5)
The operating junction temperature (TJ) for given ambient tempera-
ture (TA) can be estimated according to equation 6:
TPT
JJADIS A
#i=+
(6)
Example
An example is given below,
ƒS = 20 kHz, TA = 85 °C, VTOT = 25 V, VVCC = 5 V.
QGATE = 2.5 µC (the gate charge value here should correspond to
selected VTOT), RGINT = 2.5 W, RGON = RGOFF = 1.8 W.
PDRV = 2.5 µC × 20 kHz × 25 V = 1.25 W, according to equation 1.
PP = 5 V × 13.5 mA = 67 mW, according to equation 2 (see Figure 18).
PSNL = 25 V × 7.5 mA = 185 mW, according to equation 3 (see Figure 20).
The dissipated power under load is:
..
..
.
..
.
.,
W
P0525C 20 kHz25V
14543
145
12 43
12 03
OL
## ##
≅
n
XX
X
XX
X
=
+++
bl
according to equation 4.
RGHI = 1.45 W as maximum data sheet value.
RGHL = 1.2 W as maximum data sheet value.
RGH = RGL = 1.8 W + 2.5 W = 4.3 W.
PDIS = 67 mW + 185 mW + 300 mW = 552 mW according to equation 5.
TJ = 67 °C/W × 552 mW + 85 °C = 122 °C according to equation 6.
Estimated junction temperature for this design would be approximately
122 °C and is lower than the recommended maximum value. As the
gate charge is not adjusted to selected VTOT and internal IC resistor
values are maximum values, it is understood that the example
represents worst-case conditions.
Rev. G 05/18
8
SID11x2K
www.power.com
Table 2 describes the recommended capacitor and resistor
characteristics and layout requirements to achieve optimum
performances of SCALE-iDriver.
Pin Return to Pin Recommended
Value Symbol Notes
VCC GND 4.7 µF C1
VCC blocking capacitor needs to be placed close to IC.
Enlarged loop could result in inadequate VCC supply
voltage during operation.
VISO VEE 4.7 µF CS21/CS22
25V X7R type is recommended. Example part number
could be Murata 25 V part #GRM31CR71E475KA88.
This capacitor needs to be close to IC pins.
VEE COM 4.7 µF CS11/CS12
25 V X7R type is recommended. Example part number
could be Murata 25 V part #GRM31CR71E-475KA88.
This capacitor needs to be close to IC pins.
VGXX GH 10 nF CGXX
To avoid mis-operation, this pin should not be
connected to anything else. This capacitor needs to
be as close to IC pins as possible. 25 V X7R type is
recommended. Example part number could be Yageo
25 V part#CC0603KRX7R9BB103.
VCE COM 33 pF CRES
Select CRES to achieve needed desaturation protection
response time. 50 V COG/NPO is recommended. A
value of 33 pF is initially recommended. Example part
number could be KEMET 50 V part C0603C330J5GACTU.
Any net and any other layer should provide sufcient
distance to components CRES in order to avoid parasitic
effects (capacitance)
VCE RVCE, DVCE, CRES,
RRES, DCL
Select RVCE or RRES for the proper operation of the
short-circuit protection. Any net and any other layer
should provide sufcient distance to components RVCE,
DVCE, RRES, and DCL in order to avoid parasitic effects.
Table 2. PCB Layout and Component Guidelines.
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Thermal Resistance
Thermal Resistance: eSOP-R16B Package:
Primary-side (qJA) .............................. 51 °C/W1
Secondary-side (qJA) .......................... 67 °C/W1
Primary-side (qJC) ..............................22 °C/W2
Secondary-side (qJC) .......................... 34 °C/W2
Notes:
1. 2 oz. (610 g/m2) copper clad. Measured with layout shown in Figure 15.
2. The case temperature is measured at the plastic surface at the top
of the package.
Parameter Symbol Conditions Min Max Units
Absolute Maximum Ratings1
Primary-Side Supply Voltage2VVCC VCC to GND -0.5 6.5 V
Secondary-Side Total Supply Voltage VTOT VISO to COM -0.5 30 V
Secondary-Side Positive Supply Voltage VVISO VISO to VEE -0.5 17.5 V
Secondary-Side Negative Supply Voltage VVEE VEE to COM -0.5 15 V
Logic Input Voltage (command signal) VIN IN to GND -0.5 VVCC + 0.5 V
Logic Output Voltage (fault signal) VSO SO to GND -0.5 VVCC + 0.5 V
Logic Output Current (fault signal) ISO Positive Current Flowing into the Pin 10 mA
VCE Pin Voltage VVCE VCE - COM -0.5 VTOT + 0.5 V
Switching Frequency fS250 kHz
Storage Temperature TS-65 150 °C
Operating Junction Temperature TJ-40 1503°C
Operating Ambient Temperature TA-40 125 °C
Operating Case Temperature TC-40 125 °C
Input Power Dissipation4PPVVCC = 5 V, VTOT = 28 V,
TA = 25 °C
fS = 250 kHz
188 mW
Output Power Dissipation4PS1602
Total IC Power Dissipation4PDJS 1790 mW
NOTES:
1. Stresses beyond those listed under absolute maximum ratings may cause permanent damage to the device.
2. Dened as peak voltage measured directly on VCC pin.
3. Transmission of command signals could be affected by PCB layout parasitic inductances at junction temperatures higher than recommended.
4. Input Power Dissipation refers to equation 2. Output Power Dissipation is secondary-side IC power dissipation without capacitive load
(PSNL, equation 3) and dissipated power under load (POL, equation 4). Total IC power dissipation is sum of PP and PS.
Parameter Conditions Rating Units
Ratings for UL1577
Primary-Side
Current Rating
Current at Pin 1 (VCC)
TA = 125 °C 34 mA
Primary-Side
Power Rating TA = 25 °C 180 mW
Secondary-Side
Current Rating
Current at Pin 14 (VISO)
TA = 125 °C 27 mA
Peak Current at Pin 13 (GH) / 16 (GL), TA = 125 °C
Frequency = 250 kHz (SID1182K) 6.1
A
Peak Current at Pin 13 (GH) / 16 (GL), TA = 125 °C
Frequency = 250 kHz (SID1152K) 4
Peak Current at Pin 13 (GH) / 16 (GL), TA = 125 °C
Frequency = 250 kHz (SID1132K) 2
Secondary-Side
Power Rating TA = 25 °C 800 mW
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Parameter Symbol
Conditions
TJ = -40 °C to +125 °C
See Note 1 (Unless Otherwise Specied)
Min Typ Max Units
Recommended Operation Conditions
Primary-Side
Supply Voltage VVCC VCC ‒ GND 4.75 5.25 V
Secondary-Side
Total Supply Voltage VTOT VISO ‒ COM 22 28 V
Logic Low Input Voltage VIL 0.5 V
Logic High
Input Voltage VIH 3.3 V
Switching Frequency fS075 kHz
Operating IC Junction
Temperature TJ-40 125 °C
Electrical Characteristics
Logic Low Input
Threshold Voltage VIN+LT fS = 0 Hz 0.6 1.25 1.8 V
Logic High Input
Threshold Voltage VIN+HT fS = 0 Hz 1.7 2.2 3.05 V
Logic Input
Voltage Hysteresis VIN+HS fS = 0 Hz 0.1 V
Input Bias Current IIN
VIN = 5 V 56 113 165
µA
VIN > 3 V
See Note 12 106
Supply Current
(Primary-Side) IVCC
VIN = 0 V 4 11 17
mA
VIN = 5 V 16 23
fS = 20 kHz 14.5 20
fS = 75 kHz 16.3 23
Supply Current
(Secondary-Side) IVISO
VIN = 0 V 6 8
mA
VIN = 5 V 7 9
fS = 20 kHz 7.4 10
fS = 75 kHz 10.3 14
Power Supply
Monitoring Threshold
(Primary-Side)
UVLOVCC
Clear Fault 4.28 4.65
VSet Fault 3.85 4.12
Hysteresis, See Notes 3, 4 0.02
Power Supply
Monitoring Threshold
(Secondary-Side,
Positive Rail VVISO)
UVLOVISO
Clear Fault 12.85 13.5
VSet Fault, Note 3 11.7 12.35
Hysteresis 0.3
Power Supply Monitor-
ing Blanking Time, VVISO
UVLOVISO(BL)
Voltage Drop 13.5 V to 11.5 V
See Note 12 0.5 µs
Power Supply
Monitoring Threshold
(Secondary-Side,
Negative Rail VVEE)
UVLOVEE
Clear Fault, VTOT = 20 V 5.15 5.5
VSet Fault, VTOT = 20 V 4.67 4.93
Hysteresis 0.1
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Parameter Symbol
Conditions
TJ = -40 °C to +125 °C
See Note 1 (Unless Otherwise Specied)
Min Typ Max Units
Electrical Characteristics (cont.)
Power Supply Monitor-
ing Blanking Time, VVEE
UVLOVEE(BL)
Voltage Drop 5.5 V to 4.5 V
See Note 12 0.5 µs
Secondary-Side
Positive Supply Voltage
Regulation
VVISO(HS)
21 V ≤ VTOT ≤ 30 V,
|i(VEE)| ≤ 1.5 mA 14.4 15.07 15.75 V
VEE Source Capability IVEE(SO)
VTOT = 15 V, VVEE set to 0 V 0.1
mA
VTOT = 25 V, VVEE set to 7.5 V
See Note 13 1.85 3.3 4.5
VEE Sink Capability IVEE(SI)
VTOT = 25 V, VVEE set to 12.5 V
See Note 13 1.74 3.1 4.5 mA
DESAT Detection Level VDES VCE-VEE, VIN = 5 V 7.2 7.8 8.3 V
DESAT Sink Current IDES VVCE = 10 V, VIN = 0 V 15 28 50 mA
DESAT Bias Current IDES(BS) VVCE - VVEE = 4.5 V, VIN = 5 V -0.5 3µA
VCE Pin Capacitance CVCE Between VCE and COM pins, See Note 12 12.5 pF
Turn-On
Propagation Delay tP(LH)
TJ = 25 °C, See Note 5 180 253 340
ns
TJ = 125 °C, See Note 5 210 278 364
Turn-Off
Propagation Delay tP(HL)
TJ = 25 °C, See Note 6 200 262 330
ns
TJ = 125 °C, See Note 6 211 287 359
Minimum Turn-On and
Off Pulses tGE(MIN) See Note 12 650 ns
Output Rise Time tR
No CG, See Note 7 22 45
ns
CG = 10 nF,
See Note 7
SID1112K
See Note 12 1125
SID1132K
See Note 12 450
SID1152K
See Note 12 225
SID1182K 55 90 150
CG = 47 nF,
See Note 7
SID1112K
See Note 12 N/A
SID1132K
See Note 12 1950
SID1152K
See Note 12 975
SID1182K 300 465 650
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Parameter Symbol
Conditions
TJ = -40 °C to +125 °C
See Note 1 (Unless Otherwise Specied)
Min Typ Max Units
Electrical Characteristics (cont.)
Output Fall Time tF
No CG, See Note 8 18 45
ns
CG = 10 nF
See Note 8
SID1112K
See Note 12 1125
SID1132K
See Note 12 450
SID1152K
See Note 12 225
SID1182K 40 81 150
CG = 47 nF
See Note 8
SID1112K
See Note 12 N/A
SID1132K
See Note 12 1950
SID1152K
See Note 12 975
SID1182K 300 460 650
ASSD Rate of Change
tFSSD1 VGE change from 14.5 V to 14 V, See Note 12 60
ns
tFSSD2 VGE change from 14.5 V to 2.5 V, See Note 12 950 1828 2800
Propagation Delay Jitter See Note 12 ±5 ns
Fault Signalization
Delay Time tFAULT See Note 10 190 750 ns
SO Fault
Signalization time tSO 6.8 10 13.4 µs
Power-On
Start-Up Time tSTART See Note 11 10 ms
Gate Sourcing
Peak Current GH Pin IGH
VGH ≥ VTOT - 8.8 V
CG = 470 nF
See Note 13
SID1112K
See Note 12 0.48
A
SID1132K
See Note 12 1.2
SID1152K
See Note 12 2.4
SID1182K 3.6 4.6 5.5
RG = 0, CG = 47 nF
See Notes 2, 12, 13
SID1112K 0.96
SID1132K 2.4
SID1152K 4.8
SID1182K 7.3
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Parameter Symbol
Conditions
TJ = -40 °C to +125 °C
See Note 1 (Unless Otherwise Specied)
Min Typ Max Units
Electrical Characteristics (cont.)
Gate Sinking Peak
Current GL Pin IGL
VGL ≤ 7.5 V
CG = 470 nF
VGL is Referenced
to COM
SID1112K
See Note 12 0.52
A
SID1132K
See Note 12 1.3
SID1152K
See Note 12 2.6
SID1182K 44.8 5.5
RG = 0, CG = 47 nF
See Notes 2, 12
SID1112K 1.04
SID1132K 2.6
SID1152K 5.2
SID1182K 7.8
Turn-On Internal
Gate Resistance RGHI
I(GH) = -250 mA
VIN= 5 V
SID1112K
See Note 12 12
W
SID1132K
See Note 12 4.8
SID1152K
See Note 12 2.4
SID1182K 0.76 1.2
Turn-Off Internal
Gate Resistance RGLI
I(GL) = 250 mA
VIN = 0 V
SID1112K
See Note 12 10
W
SID1132K
See Note 12 4
SID1152K
See Note 12 2
SID1182K 0.68 1.1
Turn-On Gate
Output Voltage VGH(ON)
I(GH) = 2 mA
VIN = 5 V, See Note 13
SID1112K
See Note 12
VTOT-0.04 V
I(GH) = 6.6 mA
VIN = 5 V, See Note 13
SID1132K
See Note 12
I(GH) = 10 mA
VIN = 5 V, See Note 13
SID1152K
See Note 12
I(GH) = 20 mA
VIN = 5 V, See Note 13 SID1182K
Turn-Off Gate
Output Voltage
(Referred to COM Pin)
VGL(OFF)
I(GL) = -2 mA
VIN = 0 V
SID1112K
See Note 12
0.04 V
I(GL) = -6.6 mA
VIN = 0 V
SID1132K
See Note 12
I(GL) = -10 mA
VIN = 0 V
SID1152K
See Note 12
I(GL) = -20 mA
VIN = 0 V SID1182K
SO Output Voltage VSO(FAULT) Fault Condition, ISO = 3.4 mA, VVCC ≥ 3.9 V 210 450 mV
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Package Insulation Characteristics
Maximum Working
Isolation Voltage VIOWM 1000 VRMS
Maximum Repetitive
Peak Isolation Voltage VIORM 1414 VPEAK
Input to Output
Test Voltage VPD
Method A, After Environmental Tests
Subgroup 1, VPR = 1.6 × VIORM, t = 10 s
(qualication) Partial Discharge < 5 pC
2263
VPEAK
Method A, After Input/Output Safety Test
Subgroup 2/3, VPR = 1.2 x VIORM, t = 10 s,
(qualication) Partial Discharge < 5 pC
1697
Method B1, 100% Production Test,
VPR = 1.875 × VIORM, t = 1 s
Partial Discharge < 5 pC
2652
Maximum Transient
Isolation Voltage VIOTM
VTEST = VIOTM, t = 60 s (qualication),
t = 1 s (100% production) 8000 VPEAK
Maximum Surge
Isolation Voltage VIOSM
Test Method Per IEC 60065, 1.2/50 µs
Waveform, VTEST = 1.6 x VIOSM = 12800 V
(qualication)
8000 VPEAK
Insulation Resistance RSVIO = 500 V at TS>109W
Maximum Case
Temperature TS150 °C
Safety Total
Dissipated Power PSTA = 25 °C 1.79 W
Pollution Degree 2
Climatic Classication 40/125/21
Withstanding
Isolation Voltage VISO
VTEST = VISO, t = 60 s (qualication),
VTEST = 1.2 × VISO = 6000 VRMS, t = 1 s
(100% production)
5000 VRMS
Parameter Symbol
Conditions
TJ = -40 °C to +125 °C
See Note 1 (Unless Otherwise Specied)
Min Typ Max Units
Package Characteristics (See Notes 12, 14)
Distance Through the
Insulation DTI Minimum Internal Gap (Internal Clearance) 0.4 mm
Minimum Air Gap
(Clearance) L1 (IO1) Shortest Terminal-to-Terminal Distance
Through Air 9.5 mm
Minimum External
Tracking (Creepage) L2 (IO2) Shortest Terminal-to-Terminal Distance
Across the Package Surface 9.5 mm
Tracking Resistance
(Comparative Tracking
Index)
CTI DIN EN 60112 (VDE 0303-11): 2010-05
EN / IEC 60112:2003 + A1:2009 600
Isolation Resistance,
Input to Output
See Note 16
RIO
VIO = 500 V, TJ = 25 °C 1012
W
VIO = 500 V, 100 °C ≤ TJ ≤ TC(MAX) 1011
Isolation Capacitance,
Input to Output
See Note 16
CIO 1pF
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Figure 16. Thermal Derating Curve Showing Dependence of Limited Dissipated Power on Case Temperature
(DIN V VDE V 0884-10).
Continuous device operating is allowed until TJ and/or TC of 125 °C are reached. Thermal stress beyond those values but below thermal derating
curve may lead to permanent functional product damage. Operating beyond thermal SR derating curve may affect product reliability.
NOTES:
1. VVCC = 5 V, VTOT = 25 V; GH and GL pins are shorted together. RG = 4 W, No CG; VCC pin is connected to the SO pin through a 2 kW resistor.
The VGXX pin is connected to the GH pin through a 10 nF capacitor. Typical values are dened at TA = 25 °C; fS = 20 kHz, Duty Cycle =
50%. Positive currents are assumed to be owing into pins.
2. Pulse width ≤ 10 µs, duty cycle ≤ 1%. The maximum value is controlled by the ASIC to a safe level. There is no need to limit the current by
the application. The internal peak power is safely controlled for RG ≥ 0 and power semiconductor module input gate capacitance CIES ≤ 47 nF.
3. During very slow VVCC power-up and power-down related to VTOT, VVCC and VVEE respectively, several SO fault pulses may be generated.
4. SO pin connected to GND as long as VVCC stays below minimum value. No signal transferred from primary to secondary-side.
5. VIN potential changes from 0 V to 5 V within 10 ns. Delay is measured from 50% voltage increase on IN pin to 10% voltage increase
on GH pin.
6. VIN potential changes from 5 V to 0 V within 10 ns. Delay is measured from 50% voltage decrease on IN pin to 10% voltage decrease
on GL pin.
7. Measured from 10% to 90% of VGE (CG simulates semiconductor gate capacitance). The VGE is measured across CG.
8. Measured from 90% to 10% of VGE (CG simulates semiconductor gate capacitance). The VGE is measured across CG.
9. ASSD function limits G-E voltage of controlled semiconductor in specied time. Conditions: CG = 10 nF, VTOT = VVISO = 15 V,
VVEE = 0 V (VEE shorted to COM).
10. The amount of time needed to transfer fault event (UVLO or DESAT) from secondary-side to SO pin.
11. The amount of time after primary and secondary-side supply voltages (VVCC and VTOT) reach minimal required level for driver proper
operation. No signal is transferred from primary to secondary-side during that time, and no fault condition will be transferred from the
secondary-side to the primary-side.
12. Guaranteed by design.
13. Positive current is owing out of the pin.
14. Safety distances are application dependent and the creepage and clearance requirements should follow specic equipment isolation
standards of an application. Board design should ensure that the soldering pads of an IC maintain required safety relevant distances.
15. Measured accordingly to IEC 61000-4-8 (fS = 50 Hz, and 60 Hz) and IEC 61000-4-9.
16. All pins on each side of the barrier tied together creating a two-terminal device.
0 20 40 60 80 100 120 140 160
TC (°C)
Safe Operating Power (W)
2.0
1.8
1.4
1.6
1.2
0.6
0.8
1.0
0.4
0.0
0.2
PI-8178a-112717
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Typical Performance Characteristics
-60 -40 -20 0 20 40 100 120 1408060
Ambient Temperature (°C)
Input Bias Current I
IN (µA)
117
116
114
115
113
110
111
112
109
108
PI-7913-110716
-60 -40 -20 0 20 40 100 120 1408060
Ambient Temperature (°C)
Supply Current I
VCC (mA)
20
16
15
18
17
19
14
13
12
11
10
PI-7917-050416
IN = 0 V DC
IN = 5 V DC
fS = 20 kHz
fS = 75 kHz
050 100 150 200 250 300
Switching Frequency – fS (kHz)
Supply Current I
VCC (mA)
40
30
35
15
20
25
10
5
0
PI-7947-110716
-60 -40 0 20-20 40 100 120 1408060
Ambient Temperature (°C)
Supply Current I
VISO (mA)
11.0
10.5
9.5
9.0
10.0
7.5
8.0
8.5
7.0
6.5
6.0
PI-7915-110716
IN = 0 V DC
IN = 5 V DC
fS = 20 kHz
fS = 75 kHz
050 100 150 250 300200
Switching Frequency – f
S
(kHz)
Supply Current I
VISO (mA)
25
15
20
10
5
0
PI-7916-050416
VTOT = 22 V
VTOT = 25 V
VTOT = 28 V
Figure 17. Input Bias Current vs. Ambient Temperature.
Conditions: VVCC = 5 V, VIN = 5 V, V TOT = 25 V.
Figure 19. Supply Current Primary-Side IVCC vs. Switching Frequency.
Conditions: VVCC = 5 V, VTOT = 25 V, TJ= 25 °C, 0 Hz ≤ fS
≤ 250 kHz, No-Load.
Figure 20. Supply Current Secondary-Side IVISO vs. Ambient Temperature.
Conditions: VVCC = 5 V, VTOT = 25 V, No-Load.
Figure 18. Supply Current Primary-Side IVCC vs. Ambient Temperature.
Conditions: VVCC = 5 V, VTOT = 25 V, No-Load.
Figure 21. Supply Current Secondary-Side IVISO vs. Ambient Temperature.
Conditions: VVCC = 5 V, VTOT = 25 V, No-Load.
-60 -40 -20 0 20 40 100 120 1408060
Ambient Temperature (°C)
Propagation Delay (ns)
350
200
250
300
150
100
50
0
PI-7918-041416
tP(HL), Turn-On Delay
tP(LH), Turn-Off Delay
Figure 22. Propagation Delay Time vs. Ambient Temperature.
Conditions: VVCC = 5 V, V TOT = 25 V, fS = 20 kHz, CLOAD = 2.2 nF.
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Typical Performance Characteristics
Figure 25. Power Supply Monitoring Hysteresis UVLOVCC vs. Ambient Temperature.
Conditions: VTOT = 25 V.
Figure 24. Power Supply Monitoring UVLOVCC vs. Ambient Temperature.
Conditions: VTOT = 25 V.
Figure 23. SO Fault Signalization Time vs. Ambient Temperature.
Conditions: VVCC = 5 V, VTOT = 25 V, RSO
= 4.7 kW.
Figure 26. Power Supply Monitoring Positive Rail UVLOVISO vs. Ambient
Temperature. Conditions: VVCC = 5 V.
Figure 27 Power Supply Monitoring Positive Rail Hysteresis UVLOVISO vs. Ambient
Temperature. Conditions: VVCC = 5 V.
-60 -40 -20 0 20 40 100 120 1408060
Ambient Temperature (°C)
SO Fault Signalization Time
– tSO (µs)
12
6
8
10
4
2
0
PI-7919-110716
-60 -40 -20 0 20 40 100 120 1408060
Ambient Temperature (°C)
Primary-Side Power Supply
Monitoring UVLO
VCC (V)
4.5
2.5
3.0
3.5
4.0
1.5
2.0
0.5
1.0
0.0
PI-7921-040116
Clear Fault
Set Fault
-60 -40 -20 0 20 40 100 120 1408060
Ambient Temperature (°C)
Primary-Side Power Supply
Monitoring Hysteresis UVLO
VCC (mV)
200
120
140
160
180
80
100
20
40
60
0
PI-7922-051716
-60 -40 -20 0 20 40 100 120 1408060
Ambient Temperature (°C)
Secondary-Side Power Supply
Monitoring Positive Rail UVLO
VISO (V)
14
8
10
12
4
6
2
0
PI-7924-040116
Clear Fault
Set Fault
-60 -40 -20 0 20 40 100 120 1408060
Ambient Temperature (°C)
Secondary-Side Power Supply Monitoring
Positive Rail Hysteresis UVLO
VISO (mV)
800
500
600
700
400
100
200
300
0
PI-7923-040116
Figure 28. Power Supply Monitoring Negative Rail UVLOVEE vs. Ambient
Temperature. Conditions: VVCC = 5 V.
-60 -40 -20 0 20 40 100 120 1408060
Ambient Temperature (°C)
Secondary-Side Power Supply
Monitoring Negative Rail UVLO
VEE (V)
6
4
5
2
3
1
0
PI-7926-040116
Clear Fault
Set Fault
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Figure 32. VEE Sink Capability IVEE(SI) vs. Ambient Temperature and V VISO
.
Conditions: VVCC = 5 V, fS = 20 kHz, Duty Cycle = 50%.
Figure 31. VEE Source Capability IVEE(SO)
vs. Ambient Temperature and VVISO
.
Conditions: VVCC = 5 V, fS = 20 kHz, Duty Cycle = 50%.
Typical Performance Characteristics
Figure 30. Desaturation Detection Level VDES vs. Ambient Temperature.
Conditions: VVCC = 5 V.
Figure 29. Power Supply Monitoring Negative Rail Hysteresis UVLOVEE vs. Ambient
Temperature. Conditions: VVCC = 5 V.
-60 -40 -20 0 20 40 100 120 1408060
Ambient Temperature (°C)
Secondary-Side Power Supply Monitoring
Negative Rail Hysteresis UVLO
VEE (mV)
300
200
250
150
50
100
0
PI-7925-110716
-60 -40 -20 0 20 40 100 120 1408060
Ambient Temperature (°C)
DESAT Detection Level V
DES (V)
9.0
7.5
8.0
8.5
6.5
7.0
5.5
6.0
5.0
PI-7927-040116
VTOT = 22 V
VTOT = 25 V
VTOT = 28 V
-60 -40 -20 0 20 40 100 120 1408060
Ambient Temperature (°C)
IVEE(SI)
Sink Capability (mA)
3.50
3.30
3.25
3.35
3.45
3.40
3.20
3.05
3.15
3.10
3.00
PI-7948-050416
VTOT = 22 V and VVISO = 12.5 V
VTOT = 25 V and VVISO = 12.5 V
VTOT = 28 V and VVISO = 12.5 V
-60 -40 -20 0 20 40 100 120 1408060
Ambient Temperature (°C)
IVEE(SO)
Source Capability (mA)
3.60
3.40
3.35
3.45
3.55
3.50
3.30
3.15
3.20
3.25
3.10
PI-7928-110716
VTOT = 22 V and VVISO = 17.5 V
VTOT = 25 V and VVISO = 17.5 V
VTOT = 28 V and VVISO = 17.5 V
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PI-6995-051716
POD-eSOP-R16B Rev B
Notes:
1. Dimensioning and tolerancing per ASME Y14.5M-1994.
2. Dimensions noted are determined at the outermost extremes of the plastic body exclusive of mold
flash, tie bar burrs, gate burrs, and inter-lead flash, but including any mismatch between the top
and bottom of the plastic body. Maximum mold protrusion is 0.007 [0.18] per side.
3. Dimensions noted are inclusive of plating thickness.
4. Does not include inter-lead flash or protrusions.
5. Controlling dimensions in inches [mm].
6. Datums A and B to be determined in Datum H.
7. Exposed metal at the plastic package body outline/surface between leads 6 and 7, connected
internally to wide lead 3/4/5/6.
0.356 [9.04]Ref.
0.306 [7.77] Ref.
0.080 [2.03] Ref.
0.050 [1.27]
0.464 [11.79]
0.010 [0.25]
0.400 [10.16]
0.350 [8.89]
Pin #1 I.D.
(Laser Marked)
16 99 10 11 12 13 14 15 16
1 8 8 7 6 5 4 3 1
2
2
0.045 [1.14] Ref. 0.158 [4.01]
0.152 [3.86]
0.040 [1.02]
0.028 [0.71]
0.032 [0.81]
0.029 [0.74]
0.012 [0.30]
0.004 [0.10]
0.049 [1.23]
0.046 [1.16]
0.092 [2.34]
0.086 [2.18]
Detail A
0.105 [2.67]
0.093 [2.36]
Gauge Plane
Seating Plane
43
SIDE VIEW
TOP VIEW BOTTOM VIEW
DETAIL A
END VIEW
0.059 [1.50]
Ref. Typ.
0.010 [0.25] Ref.
0.019 [0.48]
Ref.
0.022 [0.56] Ref.
0.020 [0.51]
Ref.
0.028 [0.71]
Ref.
0.057 [1.45] Ref.
0° - 8°
0.059 [1.50]
Ref. Typ.
0.010 [0.24]
Ref.
13X
0.023 [0.58]
0.018 [0.46]
0.010 [0.25] M C A B
43
0.004 [0.10]
2X
12X
C B
0.004 [0.10]
12 Leads
Seating Plane to
Molded Bumps
Standoff
Seating
Plane
C
0.004 [0.10] 2X C A
0.006 [0.15]
8 Lead Tips
C
0.006 [0.15]
4 Lead Tips
C
B
C
H
A
0.016 [0.41]
0.011 [0.28]
C
7
3
.028 [0.71]
.070 [1.78] .460 [11.68]
.162 [4.11]
.165 [4.19]
.300 [7.62]
INCH [mm]
.350 [8.89]
.050 [1.27]
eSOP-R16B
Reference
Solder Pad
Dimensions
Rev. G 05/18
21
SID11x2K
www.power.com
MSL Table
Part Number MSL Rating
SID11x2K 3
ESD and Latch-Up Table
IEC 60664-1 Rating Table
Electrical Characteristics (EMI) Table
Test Conditions Results
Latch-up at 125 °C JESD78D > ±100 mA or > 1.5 × VMAX on all pins
Human Body Model ESD JESD22-A114F > ±2000 V on all pins
Charged Device Model ESD JESD22-C101 > ±500 V on all pins
Machine Model ESD JESD22-A115C > ±200 V on all pins
Parameter Conditions Specications
Basic Isolation Group Material Group I
Installation Classication
Rated mains voltage ≤ 150 VRMS I - IV
Rated mains voltage ≤ 300 VRMS I - IV
Rated mains voltage ≤ 600 VRMS I - IV
Rated mains voltage ≤ 1000 VRMS I - III
Parameter Symbol Conditions Min Typ Max Units
Common-Mode
Transient Immunity,
Logic High
CMH
Typical values measured according to Figures
33, 34. Maximum values are design values
assuming trapezoid waveforms
-35 / 50 -100 / 100 kV/µs
Common-Mode
Transient Immunity,
Logic Low
CML
Typical values measured according to Figures
33, 34. Maximum values are design values
assuming trapezoid waveforms
-35 / 50 -100 / 100 kV/µs
Variable Magnetic Field
Immunity
HHPEAK See Note 15 1000
A/m
HLPEAK See Note 15 1000
Figure 33. Applied Common Mode Pulses for Generating Negative dv/dt. Figure 34. Applied Common Mode Pulses for Generating Positive dv/dt.
Rev. G 05/18
22
SID11x2K
www.power.com
Regulatory Information Table
VDE UL CSA
Certied to DIN V VDE V 0884-10
(VDE V 0884-10): 2006-12
UR recognized under UL1577 Component
Recognition Program
UR recognized to CSA Component Acceptance
Notice 5A
Reinforced insulation for Max. Transient
Isolation voltage 8 kVPEAK, Max. Surge
Isolation voltage 8 kVPEAK, Max. Repetitive
Peak Isolation voltage 1414 VPEAK
Single protection, 5000 VRMS dielectric voltage
withstand
Single protection, 5000 VRMS dielectric voltage
withstand
File No. 40044363 File E358471 File E358471
Part Ordering Information
• SCALE-iDriver Product Family
• Series Number
• Package Identier
K eSOP-R16B
• Tape & Reel and Other Options
Blank Tube of 48 pcs.
TL Tape & Reel, 1000 pcs min/mult.
SID 11x2 K - TL
Rev. G 05/18
23
SID11x2K
www.power.com
Revision Notes Date
A Code S. Initial Release. 05/16
B Updated Figure 1. 06/16
C Updated Figures 1, 3, 9, 10, 13 and 14. 08/16
D
Code A. Updated Figure 3, reversed order of Figures 9 and 10, and made text corrections to pages 4, 6 and 7.
Updated IVCC, IVISO, tR, tF, tFSSD1, IGH, IGL, VSO(FAULT), IDES(BS) parameters. Moved Electrical Characteristics (EMI) parameter
section to page 20 and updated Figure 20.
10/16
E
Made updates to Abs Max Ratings table, added TC and changed TAMB to TA under Conditions on page 10. Deleted Typ value
from UVLOVISO(BL) on page 11, made changes in Conditions column for IVEE(SO), IVEE(SI), tR and tF on page 12, corrected Max
and Units value for tSTART and VGH(ON) value changes under Conditions on page 13, removed Typ value for DTI, corrected
Condition value for RIO and moved Typ values to Max column under Package Insulation Characteristic parameter on
page 14. Moved Typ value to Max column for PS on page 15, added Note 16 and updated Note 1, updated Figure 16 and
changed TJOP to TJ on page 16, minor aesthetic updates to Figures 17, 19 20, 23, corrected vertical axis label on Figure 29,
updated vertical axis values in Figure 31, updated ESD and Latch-Up table and xed capitalization in row 2, column 1 of
Regulatory Information table.
12/16
F Added Min value to IVCC parameter on page 11. Added SID1112K part number to family. 11/17
G Updated with UL approval information for VDE column in Regulatory Information table on page 22. 05/18
For the latest updates, visit our website: www.power.com
Power Integrations reserves the right to make changes to its products at any time to improve reliability or manufacturability. Power Integrations
does not assume any liability arising from the use of any device or circuit described herein. POWER INTEGRATIONS MAKES NO WARRANTY
HEREIN AND SPECIFICALLY DISCLAIMS ALL WARRANTIES INCLUDING, WITHOUT LIMITATION, THE IMPLIED WARRANTIES OF MERCHANTABILITY,
FITNESS FOR A PARTICULAR PURPOSE, AND NON-INFRINGEMENT OF THIRD PARTY RIGHTS.
Patent Information
The products and applications illustrated herein (including transformer construction and circuits external to the products) may be covered by one
or more U.S. and foreign patents, or potentially by pending U.S. and foreign patent applications assigned to Power Integrations. A complete list of
Power Integrations patents may be found at www.power.com. Power Integrations grants its customers a license under certain patent rights as set
forth at www.power.com/ip.htm.
Life Support Policy
POWER INTEGRATIONS PRODUCTS ARE NOT AUTHORIZED FOR USE AS CRITICAL COMPONENTS IN LIFE SUPPORT DEVICES OR SYSTEMS
WITHOUT THE EXPRESS WRITTEN APPROVAL OF THE PRESIDENT OF POWER INTEGRATIONS. As used herein:
1. A Life support device or system is one which, (i) is intended for surgical implant into the body, or (ii) supports or sustains life, and (iii) whose
failure to perform, when properly used in accordance with instructions for use, can be reasonably expected to result in signicant injury or
death to the user.
2. A critical component is any component of a life support device or system whose failure to perform can be reasonably expected to cause the
failure of the life support device or system, or to affect its safety or effectiveness.
The PI logo, TOPSwitch, TinySwitch, SENZero, SCALE, SCALE-iDriver, SCALE-iFlex, Qspeed, PeakSwitch, LYTSwitch, LinkZero, LinkSwitch,
InnoSwitch, HiperTFS, HiperPFS, HiperLCS, DPA-Switch, CAPZero, Clampless, EcoSmart, E-Shield, Filterfuse, FluxLink, StakFET, PI Expert and PI
FACTS are trademarks of Power Integrations, Inc. Other trademarks are property of their respective companies. ©2018, Power Integrations, Inc.
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