UCC27282-Q1
SLUSDN5B – SEPTEMBER 2019 – REVISED JULY 2021
UCC27282-Q1 Automotive 120-V Half-Bridge Driver
with Cross Conduction Protection and Low Switching Losses
1 Features
3 Description
•
The UCC27282-Q1 is a robust N-channel MOSFET
driver with a maximum switch node (HS) voltage
rating of 100 V. It allows for two N-channel MOSFETs
to be controlled in half-bridge or synchronous buck
configuration based topologies. Its 3.5-A peak sink
current and 2.5-A peak source current along with
low pull-up and pull-down resistance allows the
UCC27282-Q1 to drive large power MOSFETs with
minimum switching losses during the transition of
the MOSFET Miller plateau. Since the inputs are
independent of the supply voltage, UCC27282-Q1 can
be used in conjunction with both analog and digital
controllers.
•
•
•
•
•
•
•
•
•
•
•
•
•
AEC-Q100 qualified with following results
– Temperature grade 1 (Tj = –40°C to 150°C)
– HBM ESD classification level 1B
– CDM ESD classification level C3
Drives two N-channel MOSFETs in high-side lowside configuration
5-V typical under voltage lockout
Input interlock
Enable/disable functionality in DRC package
16-ns typical propagation delay
12-ns rise, 10-ns fall time with 1.8-nF load
1-ns typical delay matching
Absolute Maximum Negative Voltage Handling on
Inputs (–5 V)
Absolute Maximum Negative Voltage Handling on
HS (–14 V)
3.5-A sink, 2.5-A Source output currents
Absolute maximum boot voltage 120 V
Low current (7-µA) consumption when disabled
Integrated bootstrap diode
2 Applications
•
•
•
•
•
Automotive DC/DC converters
Electric power steering
On-board charger (OBC)
Integrated belt starter generator (iBSG)
Automotive HVAC compressor modules
7V
75V
VDD
EN
HO
NC
HI
HB
LI
HS
VSS
LO
To Load
The input pins as well as the HS pin are able to
tolerate significant negative voltage, which improves
system robustness. Input interlock further improves
robustness and system reliability in high noise
applications. The enable and disable functionality
provides additional system flexibility by reducing
power consumption by the driver and responds to
fault events within the system. 5-V UVLO allows
systems to operate at lower bias voltages, which
is necessary in many high frequency applications
and improves system efficiency in certain operating
modes. Small propagation delay and delay matching
specifications minimize the dead-time requirement
which further improves efficiency.
Under voltage lockout (UVLO) is provided for both
the high-side and low-side driver stages forcing the
outputs low if the VDD voltage is below the specified
threshold. An integrated bootstrap diode eliminates
the need for an external discrete diode in many
applications, which saves board space and reduces
system cost. UCC27282-Q1 is offered in a small
package enabling high density designs.
Device Information(1)
PART NUMBER
0 …F
PACKAGE (DESIGNATOR) (SIZE)
SON10 (DRC) (3 mm x 3 mm)
UCC27282-Q1
SOIC8 (D) (6 mm x 5mm)
SOIC8-PP (DDA) (6 mm x 5mm)
(1)
For all available packages, see the orderable addendum at
the end of the data sheet.
Simplified Application Diagram
An IMPORTANT NOTICE at the end of this data sheet addresses availability, warranty, changes, use in safety-critical applications,
intellectual property matters and other important disclaimers. PRODUCTION DATA.
UCC27282-Q1
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SLUSDN5B – SEPTEMBER 2019 – REVISED JULY 2021
Table of Contents
1 Features............................................................................1
2 Applications..................................................................... 1
3 Description.......................................................................1
4 Revision History.............................................................. 2
5 Pin Configuration and Functions...................................3
6 Specifications.................................................................. 4
6.1 Absolute Maximum Ratings........................................ 4
6.2 ESD Ratings............................................................... 4
6.3 Recommended Operating Conditions.........................4
6.4 Thermal Information....................................................5
6.5 Electrical Characteristics.............................................5
6.6 Switching Characteristics............................................6
6.7 Timing Diagrams......................................................... 7
6.8 Typical Characteristics................................................ 7
7 Detailed Description......................................................13
7.1 Overview................................................................... 13
7.2 Functional Block Diagram......................................... 13
7.3 Feature Description...................................................13
7.4 Device Functional Modes..........................................16
8 Application and Implementation.................................. 17
8.1 Application Information............................................. 17
8.2 Typical Application.................................................... 18
9 Power Supply Recommendations................................26
10 Layout...........................................................................27
10.1 Layout Guidelines................................................... 27
10.2 Layout Example...................................................... 27
11 Device and Documentation Support..........................28
11.1 Third-Party Products Disclaimer............................. 28
11.2 Receiving Notification of Documentation Updates.. 28
11.3 Support Resources................................................. 28
11.4 Trademarks............................................................. 28
11.5 Electrostatic Discharge Caution.............................. 28
11.6 Glossary.................................................................. 28
4 Revision History
Changes from Revision A (January 2020) to Revision B (March 2021)
Page
• Added 8-Pin DDA package. ...............................................................................................................................3
Changes from Revision * (September 2019) to Revision A (June 2020)
Page
• Changed marketing status from Advance Information to initial release. ............................................................1
2
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5 Pin Configuration and Functions
VDD
NC
HB
HO
HS
1
2
3
4
5
10
9
Thermal
8
Pad
7
6
LO
VSS
LI
HI
EN
VDD
1
8
LO
HB
2
7
VSS
HO
3
6
LI
HS
4
5
HI
Not to scale
Not to scale
Figure 5-1. DRC Package 10-Pin VSON With
Exposed Thermal Pad (Top View)
VDD
1
HB
2
Figure 5-2. D Package 8-Pin SOIC (Top View)
8
LO
7
VSS
6
LI
5
HI
Thermal
HO
3
HS
4
Pad
Not to scale
Figure 5-3. DDA Package 8-Pin SOIC With Exposed Thermal Pad (Top View)
Table 5-1. Pin Functions
PIN
Name
DDA
D
DRC
EN
n/a
n/a
6
I/O(1)
DESCRIPTION
I
Enable input. When this pin is pulled high, it will enable the driver. If left floating
or pulled low, it will disable the driver. 1 nF filter capacitor is recommended for
high-noise systems.
HB
2
2
3
P
High-side bootstrap supply. The bootstrap diode is on-chip but the external
bootstrap capacitor is required. Connect positive side of the bootstrap capacitor
to this pin. Typical recommended value of HB bypass capacitor is 0.1 μF, This
value primarily depends on the gate charge of the high-side MOSFET. When
using external boot diode, connect cathode of the diode to this pin.
HI
5
5
7
I
High-side input.
HO
3
3
4
O
High-side output. Connect to the gate of the high-side power MOSFET or one
end of external gate resistor, when used.
HS
4
4
5
P
High-side source connection. Connect to source of high-side power MOSFET.
Connect negative side of bootstrap capacitor to this pin.
LI
6
6
8
I
Low-side input
LO
8
8
10
O
Low-side output. Connect to the gate of the low-side power MOSFET or one
end of external gate resistor, when used.
NC
n/a
n/a
2
—
Not connected internally.
VDD
1
1
1
P
Positive supply to the low-side gate driver. Decouple this pin to VSS. Typical
decoupling capacitor value is 1 μF. When using an external boot diode, connect
the anode to this pin.
VSS
7
7
9
G
Negative supply terminal for the device which is generally the system ground.
Thermal
pad
—
n/a
—
—
Connect to a large thermal mass trace (generally IC ground plane) to improve
thermal performance. This can only be electrically connected to VSS.
(1)
P = Power, G = Ground, I = Input, O = Output, I/O = Input/Output
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6 Specifications
6.1 Absolute Maximum Ratings
All voltages are with respect to Vss (1) (2)
VDD
Supply voltage
VEN, VHI, VLI
Input voltages on EN, HI and LI
DC
MIN
MAX
UNIT
–0.3
20
V
V
–5
20
–0.3
VDD + 0.3
–2
VDD + 0.3
VHS – 0.3
VHB + 0.3
VHS – 2
VHB + 0.3
–10
100
–14
100
VLO
Output voltage on LO
VHO
Output voltage on HO
VHS
Voltage on HS
VHB
Voltage on HB
–0.3
120
V
VHB-HS
Voltage on HB with respect to HS
–0.3
20
V
TJ
Operating junction temperature
–40
150
°C
300
°C
150
°C
Pulses < 100 ns(3)
DC
Pulses < 100
ns(3)
DC
Pulses < 100
ns(3)
Lead temperature (soldering, 10 sec.)
Tstg
(1)
(2)
(3)
Storage temperature
–65
V
V
V
Operation outside the Absolute Maximum Ratings may cause permanent device damage. Absolute Maximum Ratings do not imply
functional operation of the device at these or any other conditions beyond those listed under Recommended Operating Conditions. If
outside the Recommended Operating Conditions but within the Absolute Maximum Ratings, the device may not be fully functional, and
this may affect device reliability, functionality, performance, and shorten the device lifetime.
All voltages are with respect to Vss. Currents are positive into, negative out of the specified terminal.
Values are verified by characterization only.
6.2 ESD Ratings
VALUE
V(ESD)
(1)
(2)
Electrostatic discharge
Human-body model (HBM), per AEC Q100-002
(1) (2)
±2000
Charged-device model (CDM), per AEC Q100-011
±1500
UNIT
V
AEC Q100-002 indicates that HBM stressing shall be in accordance with the ANSI/ESDA/JEDEC JS-001 specification..
Pins HS, HB and HO are rated at 500V HBM
6.3 Recommended Operating Conditions
over operating free-air temperature range (unless otherwise noted)
NOM
MAX
UNIT
5.5
12
16
V
Supply voltage
VEN, VHI, VLI
Input Voltage
0
VDD+0.3
VLO
Low side output voltage
0
VDD+0.3
VHO
High side output voltage
VHS
VHB+0.3
Voltage on HS(1)
–8
100
–12
100
VHS + 5.5
VHS+16
V
50
V/ns
–40
150
°C
VHS
Voltage on HS (Pulses < 100
ns)(1)
VHB
Voltage on HB
Vsr
Voltage slew rate on HS
TJ
Operating junction temperature
(1)
4
MIN
VDD
V
VHB-HS < 16V (Voltage on HB with respect to HS must be less than 16V)
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6.4 Thermal Information
UCC27282-Q1
THERMAL
METRIC(1)
UNIT
DDA
D
DRC
8 PINS
8 PINS
10 PINS
RθJA
Junction-to-ambient thermal resistance
40.8
118.3
47.3
°C/W
RθJC(top)
Junction-to-case (top) thermal resistance
54.4
53.6
50.3
°C/W
RθJB
Junction-to-board thermal resistance
16.4
63.1
21.3
°C/W
ψJT
Junction-to-top characterization parameter
4.1
10.7
1.0
°C/W
ψJB
Junction-to-board characterization parameter
16.4
62.1
21.2
°C/W
RθJC(bot)
Junction-to-case (bottom) thermal resistance
4.9
n/a
4.4
°C/W
(1)
For more information about traditional and new thermal metrics, see the Semiconductor and IC Package Thermal Metrics application
report, SPRA953.
6.5 Electrical Characteristics
VDD = VHB = VEN =12 V, VHS = VSS = 0 V, No load on LO or HO, TJ = –40°C to +150°C, (unless otherwise noted)
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX UNIT
SUPPLY CURRENTS
IDD
VDD quiescent current
VLI = VHI = 0
0.3
0.4
mA
IDDO
VDD operating current
f = 500 kHz, CLOAD = 0
2.2
4.5
mA
IHB
HB quiescent current
VLI = VHI = 0 V
0.2
0.4
mA
IHBO
HB operating current
f = 500 kHz, CLOAD = 0
2.5
4
mA
IHBS
HB to VSS quiescent current
VHS = VHB = 110 V
2.0
50
IHBSO
HB to VSS operating current(1)
f = 500 kHz, CLOAD = 0
0.1
mA
IDD_DIS
IDD when driver is disabled
VEN = 0
7.0
μA
μA
INPUT
VHIT
Input rising threshold
1.9
2.1
2.4
V
VLIT
Input falling threshold
0.9
1.1
1.3
V
VIHYS
Input voltage Hysteresis
RIN
Input pulldown resistance
100
250
350
kΩ
1.54
2.0
V
1.0
V
ENABLE
VEN
Voltage threshold on EN pin to enable the driver
VDIS
Voltage threshold on EN pin to disable the driver
1.21
V
VENHYS
Enable pin Hysteresis
0.3
V
REN
EN pin internal pull-down resistor
250
kΩ
TEN
Time to enable the driver once the EN pin is
pulled high
VEN = 2V
18
μs
TDIS
Time to disable the driver once the EN pin is
pulled low
VEN = 0V
1.5
μs
0.7
UNDERVOLTAGE LOCKOUT PROTECTION (UVLO)
VDDR
VDD rising threshold
4.7
5.0
5.4
V
VDDF
VDD falling threshold
4.2
4.5
4.9
V
VDDHYS
VDD threshold hysteresis
VHBR
HB rising threshold with respect to HS pin
3.3
3.7
4.7
V
VHBF
HB falling threshold with respect to HS pin
3.0
3.3
4.4
V
VHBHYS
HB threshold hysteresis
0.5
V
0.3
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6.5 Electrical Characteristics (continued)
VDD = VHB = VEN =12 V, VHS = VSS = 0 V, No load on LO or HO, TJ = –40°C to +150°C, (unless otherwise noted)
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX UNIT
BOOTSTRAP DIODE
VF
Low-current forward voltage
IVDD-HB = 100 μA
0.55
0.85
V
VFI
High-current forward voltage
IVDD-HB = 80 mA
0.88
1.1
V
RD
Dynamic resistance, ΔVF/ΔI
IVDD-HB = 100 mA and 80 mA
1.5
2.5
Ω
LO GATE DRIVER
VLOL
Low level output voltage
ILO = 100 mA
0.085
0.4
V
VLOH
High level output voltage
ILO = -100 mA, VLOH = VDD – VLO
0.13
0.42
V
VLO = 0 V
2.5
A
VLO = 12 V
3.5
A
Peak pullup current
(1)
Peak pulldown current (1)
HO GATE DRIVER
VHOL
Low level output voltage
IHO = 100 mA
0.1
0.4
V
VHOH
High level output voltage
IHO = –100 mA, VHOH = VHB- VHO
0.13
0.42
V
Peak pullup current (1)
VHO = 0 V
2.5
A
VHO = 12 V
3.5
A
(1)
Peak pulldown current
(1)
Parameter not tested in production
6.6 Switching Characteristics
VDD = VHB = 12 V, VHS = VSS = 0 V, No load on LO or HO, TJ = –40°C to +150°C, (unless otherwise noted)
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX
UNIT
PROPAGATION DELAYS
tDLFF
VLI falling to VLO falling
See Section 6.7
16
30
ns
tDHFF
VHI falling to VHO falling
See Section 6.7
16
30
ns
tDLRR
VLI rising to VLO rising
See Section 6.7
16
30
ns
tDHRR
VHI rising to VHO rising
See Section 6.7
16
30
ns
DELAY MATCHING
tMON
From LO being ON to HO being OFF
See Section 6.7
1
7
ns
tMOFF
From LO being OFF to HO being ON
See Section 6.7
1
7
ns
OUTPUT RISE AND FALL TIME
tR
LO, HO rise time
CLOAD = 1800 pF, 10% to 90%
12
ns
tF
LO, HO fall time
CLOAD = 1800 pF, 90% to 10%
10
ns
tR
LO, HO (3 V to 9 V) rise time
CLOAD = 0.1 μF, 30% to 70%
0.33
0.6
μs
tF
LO, HO (3 V to 9 V) fall time
CLOAD = 0.1 μF, 70% to 30%
0.23
0.6
μs
MISCELLANEOUS
TPW,min
Minimum input pulse width that changes the output
Bootstrap diode turnoff
(1)
6
time(1)
IF = 20 mA, IREV = 0.5 A
20
ns
50
ns
Parameter not tested in production
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6.7 Timing Diagrams
LI
Voltage (V)
Voltage (V)
HI
Input
(HI, LI)
LO
TDLRR, TDHRR
Output
(HO, LO)
HO
Time (s)
TDLFF,
TDHFF
Time (s)
TMOFF
TMON
6.8 Typical Characteristics
Unless otherwise specified VVDD=VHB = 12 V, VHS=VVSS = 0 V, No load on outputs
0.22
0.3
0.26
0.24
0.22
0.2
0.18
0.16
0.14
5.5V
12V
16V
0.12
0.1
-40
A.
HB Quiescent Current (mA)
VDD Quiescent Current (mA)
0.28
-15
10
35
60
85
Temperature (°C)
110
0.18
0.14
0.1
0.06
0.02
-40
135 150
5.5V
12V
16V
-15
IDDQ
A.
VHI = VLI = 0 V
Figure 6-1. VDD Quiescent Current
10
35
60
85
Temperature (°C)
110
135 150
IHBQ
VHI = VLI = 0 V
Figure 6-2. HB Quiescent Current
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6
4.5
-40°C
25°°C
150°°C
5
3.5
3
IHBO (mA)
4
IDDO (mA)
-40°C
25°C
150°C
4
3
2.5
2
1.5
2
1
1
0.5
0
0
1
2
3 4 5 67 10
20 30 50 70100
Frequency (kHz)
200
1
500 1000
14
200
500 1000
IHBO
18
15
IHBS (PA)
10
IDD_DIS (PA)
20 30 50 70100
Frequency (kHz)
21
5.5V
12V
16V
12
8
6
12
9
4
6
2
3
0
-40
-15
10
A.
35
60
85
Temperature (°C)
110
0
-40
135 150
-15
10
IDD_
A.
VEN = 0 V
35
60
85
Temperature (°C)
110
135 150
IHBS
VHB=VHS=100V
Figure 6-6. HB to VSS Quiescent Current
Figure 6-5. VDD Current When Disabled
2.22
1.145
1.14
Input Falling Threshold (V)
2.21
Input Rising Threshold (V)
3 4 5 67 10
Figure 6-4. HB Operating Current
Figure 6-3. VDD Operating Current
2.2
2.19
2.18
5.5V
12V
16V
2.17
2.16
-40
-15
10
35
60
85
Temperature (°C)
110
1.135
1.13
1.125
1.12
1.115
5.5V
12V
16V
1.11
135 150
1.105
-40
-15
IN_R
Figure 6-7. Input Rising Threshold
8
2
IDDO
10
35
60
85
Temperature (°C)
110
135 150
IN_F
Figure 6-8. Input Falling Threshold
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1.8
280
Enable Threshold (V)
Input Resistance (k:)
270
260
250
240
1.6
1.5
1.4
1.3
230
-40
-15
10
35
60
85
Temperature (°C)
110
1.2
-40
135 150
-15
10
R_IN
Figure 6-9. Input Pull-down Resistor
35
60
85
Temperature (°C)
110
135 150
EN_T
Figure 6-10. Enable Threshold
70
1.35
5.5V
12V
16V
1.3
1.25
5.5V
12V
16V
60
Enable Delay (Ps)
Disable Threshold (V)
5.5V
12V
16V
1.7
1.2
1.15
1.1
1.05
50
40
30
1
20
0.95
0.9
-40
-15
10
35
60
85
Temperature (°C)
110
10
-40
135 150
Figure 6-11. Disable Threshold
110
135 150
T_EN
5
VDD UVLO (V)
Disable Delay (Ps)
35
60
85
Temperature (°C)
5.2
5.5V
12V
16V
2
1.9
1.8
4.8
4.6
4.4
1.7
1.6
-40
10
Figure 6-12. Enable Delay
2.2
2.1
-15
Dis_
Rise
Fall
-15
10
35
60
85
Temperature (°C)
110
135 150
4.2
-40
-15
T_Di
Figure 6-13. Disable Delay
10
35
60
85
Temperature (°C)
110
135 150
VDDU
Figure 6-14. VDD UVLO Threshold
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4
1
100uA
80mA
Diode Forward Voltage (V)
HB UVLO (V)
3.8
3.6
3.4
3.2
0.8
0.6
0.4
Rise
Fall
3
-40
-15
10
35
60
85
Temperature (°C)
110
0.2
-40
135 150
Figure 6-15. HB UVLO Threshold
10
35
60
85
Temperature (°C)
110
135 150
Vfq1
Figure 6-16. Boot Diode Forward Voltage Drop
1.8
0.14
1.7
0.12
Output Voltage (V)
Diode Dynamic Resistance (:)
-15
HBUV
1.6
1.5
1.4
0.1
0.08
5.5V
12V
16V
1.3
1.2
-40
-15
10
35
60
85
Temperature (°C)
110
0.06
-40
135 150
-15
10
35
60
85
Temperature (°C)
110
135 150
V_LO
R_Dy
Figure 6-17. Boot Diode Dynamic Resistance
A.
IO=100mA
Figure 6-18. LO Low Output Voltage (VLOL)
0.16
0.22
0.2
Output Voltage (V)
Output Voltage (V)
0.14
0.18
0.16
0.14
0.12
0.1
5.5V
12V
16V
0.12
0.1
-40
A.
-15
10
35
60
85
Temperature (°C)
110
5.5V
12V
16V
-15
V_LO
IO=-100mA
A.
Figure 6-19. LO High Output Voltage (VLOH)
10
0.08
-40
135 150
10
35
60
85
Temperature (°C)
110
135 150
UCC2
V_HO
IO=100mA
Figure 6-20. HO Low Output Voltage (VHOL)
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0.2
15
0.18
14
LO Rise Time (ns)
Output Voltage (V)
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0.16
0.14
0.12
5.5V
12V
16V
0.1
0.08
-40
A.
-15
10
35
60
85
Temperature (°C)
110
5.5V
12V
16V
13
12
11
10
9
-40
135 150
IO=-100mA
A.
10
35
60
85
Temperature (°C)
110
135 150
LO_R
CL=1800pF
Figure 6-21. HO High Output Voltage (VHOH)
Figure 6-22. LO Rise Time
18
10.5
10
-15
V_HO
5.5V
12V
16V
5.5V
12V
16V
HO Rise Time (ns)
LO Fall Time (ns)
15
9.5
9
9
8.5
8
-40
A.
12
-15
10
35
60
85
Temperature (°C)
110
6
-40
135 150
CL=1800pF
A.
35
60
85
Temperature (°C)
110
135 150
HO_R
Figure 6-24. HO Rise Time
9
0.41
5.5V
12V
16V
8.7
0.38
0.35
8.4
Time (Ps)
HO Fall Time (ns)
10
CL=1800pF
Figure 6-23. LO Fall Time
8.1
7.8
0.32
0.29
0.26
7.5
0.23
7.2
-40
A.
-15
LO_F
-15
10
35
60
85
Temperature (°C)
110
Rise
Fall
0.2
-40
135 150
-15
10
35
60
85
Temperature (°C)
110
HO_F
A.
CL=1800pF
Figure 6-25. HO Fall Time
135 150
LO_R
CL=100nF
Figure 6-26. LO Rise & Fall Time
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20
0.47
0.43
19
18
0.35
Time (ns)
Time (Ps)
0.39
0.31
0.27
17
16
0.23
0.19
0.15
-40
A.
-15
10
35
60
85
Temperature (°C)
110
5.5V
12V
16V
15
Rise
Fall
14
-40
135 150
-15
10
HO_R
CL=100nF
35
60
85
Temperature (°C)
110
135 150
TDHR
Figure 6-28. HO Rising Propagation Delay (TDHRR)
Figure 6-27. HO Rise & Fall Time
19
20
18.5
19.5
19
18
18.5
Time (ns)
Time (ns)
17.5
17
16.5
16
17
16.5
15.5
16
5.5V
12V
16V
15
14.5
-40
18
17.5
-15
10
35
60
85
Temperature (°C)
110
5.5V
12V
16V
15.5
135 150
15
-40
-15
10
TDLF
35
60
85
Temperature (°C)
110
135 150
TDLR
Figure 6-29. HO Falling Propagation Delay (TDHFF) Figure 6-30. LO Rising Propagation Delay (TDLRR)
19
18.5
18
Time (ns)
17.5
17
16.5
16
15.5
5.5V
12V
16V
15
14.5
-40
-15
10
35
60
85
Temperature (°C)
110
135 150
TDLF
Figure 6-31. LO Falling Propagation Delay (TDLFF)
12
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7 Detailed Description
7.1 Overview
The UCC27282-Q1 is a high-voltage gate driver designed to drive both the high-side and the low-side N-channel
FETs in a synchronous buck or a half-bridge configurations. The two outputs are independently controlled with
two TTL-compatible input signals. The device can also work with CMOS type control signals at its inputs as long
as signals meet turn-on and turn-off threshold specifications of the UCC27282-Q1. The floating high-side driver
is capable of working with HS voltage up to 100 V with respect to VSS. A 100 V bootstrap diode is integrated in
the UCC27282-Q1 device to charge high-side gate drive bootstrap capacitor. A robust level shifter operates at
high speed while consuming low power and provides clean level transitions from the control logic to the high-side
gate driver. Undervoltage lockout (UVLO) is provided on both the low-side and the high-side power rails. EN
pin is provided (in DRC packaged parts) to enable or disable the driver. The driver also has input interlock
functionality, which shuts off both the outputs when the two inputs overlap.
7.2 Functional Block Diagram
HB
UVLO
DRIVER
STAGE
LEVEL
SHIFT
HO
HS
HI
VDD
EN
UVLO
DRIVER
STAGE
LO
Interlock Logic
VSS
LI
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7.3 Feature Description
7.3.1 Enable
The device in DRC package has an enable (EN) pin. The outputs will be active only if the EN pin voltage
is above the threshold voltage. Outputs will be held low if EN pin is left floating or pulled-down to ground.
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An internal 250 kΩ resistor connects EN pin to VSS pin. Thus, leaving the EN pin floating disables the
device. Externally pulling EN pin to ground shall also disable the device. If the EN pin is not used, then it is
recommended to connect it to VDD pin. If a pull-up resistor needs to be used then a strong pull-up resistor is
recommended. For 12V supply voltage, a 10kΩ pull-up is suggested. In noise prone application, a small filter
capacitor, 1nF, should be connected from the EN pin to VSS pin as close to the device as possible. An analog
or a digital controller output pin could be connected to EN pin to enable or disable the device. Built-in hysteresis
helps prevent any nuisance tripping or chattering of the outputs.
7.3.2 Start-up and UVLO
Both the high-side and the low-side driver stages include UVLO protection circuitry which monitors the supply
voltage (VDD) and the bootstrap capacitor voltage (VHB–HS). The UVLO circuit inhibits each output until sufficient
supply voltage is available to turn on the external MOSFETs. The built-in UVLO hysteresis prevents chattering
during supply voltage variations. When the supply voltage is applied to the VDD pin of the device, both the
outputs are held low until VDD exceeds the UVLO threshold, typically 5 V. Any UVLO condition on the bootstrap
capacitor (VHB–HS) disables only the high- side output (HO).
Table 7-1. VDD UVLO Logic Operation
Condition (VHB-HS > VHBR and VEN > Enable Threshold)
VDD-VSS < VDDR during device start-up
VDD-VSS < VDDR – VDDH after device start-up
HI
LI
HO
LO
H
L
L
L
L
H
L
L
H
H
L
L
L
L
L
L
H
L
L
L
L
H
L
L
H
H
L
L
L
L
L
L
HI
LI
HO
LO
H
L
L
L
L
H
L
H
H
H
L
L
L
L
L
L
H
L
L
L
Table 7-2. HB UVLO Logic Operation
Condition (VDD > VDDR and VEN > Enable Threshold)
VHB-HS < VHBR during device start-up
VHB-HS < VHBR – VHBH after device start-up
L
H
L
H
H
H
L
L
L
L
L
L
7.3.3 Input Stages and Interlock
The two inputs operate independently, with an exception that both outputs will be pulled low when both inputs
are high or overlap. The independence allows for full control of two outputs compared to the gate drivers that
have a single input. The device has input interlock or cross-conduction protection. Whenever both the inputs are
high, the internal logic turns both the outputs off. Once the device is in shoot-through mode, when one of the
inputs goes low, the outputs follow the input logic. There is no other fixed time de-glitch filter implemented in the
device and therefore propagation delay and delay matching are not sacrificed. In other words, there is no built-in
dead-time due to the interlock feature. Any noise on the input that could cause the output to shoot-through will
be filtered by this feature and the system stays protected. Because the inputs are independent of supply voltage,
they can be connected to outputs of either digital controller or analog controller. Inputs can accept wide slew
rate signals and input can withstand negative voltage to increase the robustness. Small filter at the inputs of
the driver further improves system robustness in noise prone applications. The inputs have internal pull down
resistors with typical value of 250 kΩ. Thus, when the inputs are floating, the outputs are held low.
14
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HI
LI
LO
Interlock
HO
Time
Figure 7-1. Interlock or Input Shoot-through Protection
7.3.4 Level Shifter
The level shift circuit is the interface from the high-side input, which is a VSS referenced signal, to the high-side
driver stage which is referenced to the switch node (HS pin). The level shift allows control of the HO output
which is referenced to the HS pin. The delay introduced by the level shifter is kept as low as possible and
therefore the device provides excellent propagation delay characteristic and delay matching with the low-side
driver output. Low delay matching allows power stages to operate with less dead time. The reduction in deadtime is very important in applications where high efficiency is required.
7.3.5 Output Stage
The output stages are the interface from level shifter output to the power MOSFETs in the power train. High slew
rate, low resistance, and high peak current capability of both outputs allow for efficient switching of the power
MOSFETs. The low-side output stage is referenced to VSS and the high-side is referenced to HS. The device
output stages are robust to handle harsh environment, such as –2 V transient for 100 ns. The device can also
sustain positive transients on the outputs. The device output stages feature a pull-up structure which delivers the
highest peak source current when it is most needed, during the Miller plateau region of the power switch turn on
transition. The output pull-up and pull-down structure of the device is totem pole NMOS-PMOS structure.
7.3.6 Negative Voltage Transients
In most applications, the body diode of the external low-side power MOSFET clamps the HS node to ground.
In some situations, board capacitances and inductances can cause the HS node to transiently swing several
volts below ground, before the body diode of the external low-side MOSFET clamps this swing. When used in
conjunction with the UCC27282-Q1, the HS node can swing below ground as long as specifications are not
violated and conditions mentioned in this section are followed.
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HS must always be at a lower potential than HO. Pulling HO more negative than specified conditions can
activate parasitic transistors which may result in excessive current flow from the HB supply. This may result in
damage to the device. The same relationship is true with LO and VSS. If necessary, a Schottky diode can be
placed externally between HO and HS or LO and VSS to protect the device from this type of transient. The diode
must be placed as close to the device pins as possible in order to be effective.
Ensure that the HB to HS operating voltage is 16 V or less. Hence, if the HS pin transient voltage is –5 V,
then VDD (and thus HB) is ideally limited to 11 V to keep the HB to HS voltage below 16 V. Generally when
HS swings negative, HB follows HS instantaneously and therefore the HB to HS voltage does not significantly
overshoot.
Low ESR bypass capacitors from HB to HS and from VDD to VSS are essential for proper operation of the gate
driver device. The capacitor should be located at the leads of the device to minimize series inductance. The
peak currents from LO and HO can be quite large. Any series inductances with the bypass capacitor causes
voltage ringing at the leads of the device which must be avoided for reliable operation.
Based on application board design and other operating parameters, along with HS pin, other pins such as inputs,
HI and LI, might also transiently swing below ground. To accommodate such operating conditions UCC27282-Q1
input pins are capable of handling absolute maximum of -5V. As explained earlier, based on the layout and other
design constraints, some times the outputs, HO and LO, might also see transient voltages for short durations.
Therefore, UCC27282-Q1 gate drivers can also handle -2 V 100 ns transients on output pins, HO and LO.
7.4 Device Functional Modes
When the device is enabled, the device operates in normal mode and UVLO mode. See Section 7.3.2 for more
information on UVLO operation mode. In normal mode when the VDD and VHB–HS are above UVLO threshold,
the output stage is dependent on the states of the EN, HI and LI pins. The output HO and LO will be low if input
state is floating.
Table 7-3. Input/Output Logic in Normal Mode of Operation
EN
L
H
H
Floating
(1)
(2)
16
HI
LI
HO (1)
LO (2)
H
H
L
L
L
H
L
L
H
L
L
L
L
L
L
L
H
H
L
L
L
H
L
H
H
L
H
L
L
L
L
L
Floating
L
L
L
Floating
H
L
H
L
Floating
L
L
H
Floating
H
L
Floating
Floating
L
L
HO is measured with respect to HS
LO is measured with respect to VSS
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8 Application and Implementation
Note
Information in the following applications sections is not part of the TI component specification, and
TI does not warrant its accuracy or completeness. TI’s customers are responsible for determining
suitability of components for their purposes. Customers should validate and test their design
implementation to confirm system functionality.
8.1 Application Information
Most electronic devices and applications are becoming more and more power hungry. These applications are
also reducing in overall size. One way to achieve both high power and low size is to improve the efficiency
and distribute the power loss optimally. Most of these applications employ power MOSFETs and they are being
switched at higher and higher frequencies. To operate power MOSFETs at high switching frequencies and to
reduce associated switching losses, a powerful gate driver is employed between the PWM output of controller
and the gates of the power semiconductor devices, such as power MOSFETs, IGBTs, SiC FETs, and GaN FETs.
Many of these applications require proper UVLO protection so that power semiconductor devices are turned ON
and OFF optimally. Also, gate drivers are indispensable when it is impossible for the PWM controller to directly
drive the gates of the switching devices. With the advent of digital power, this situation is often encountered
because the PWM signal from the digital controller is often a 3.3-V logic signal which cannot effectively turn on
a power switch. A level-shift circuit is needed to boost the 3.3-V signal to the gate-drive voltage (such as 12
V or 5 V) in order to fully turn-on the power device, minimize conduction losses, and minimize the switching
losses. Traditional buffer drive circuits based on NPN/PNP bipolar transistors in totem-pole arrangement prove
inadequate with digital power because they lack level-shifting capability and under voltage lockout protection.
Gate drivers effectively combine both the level-shifting and buffer-drive functions. Gate drivers also solve other
problems such as minimizing the effect of high-frequency switching noise (by placing the high-current driver
device physically close to the power switch), driving gate-drive transformers and controlling floating power device
gates. This helps reduce power dissipation and thermal stress in controllers by moving gate charge power losses
from the controller IC to the gate driver.
UCC27282-Q1 gate drivers offer high voltage (100 V), small delays (16 ns), and good driving capability (2.5
A/3.5 A) in a single device. The floating high-side driver is capable of operating with switch node voltages up
to 100 V. This allows for N-channel MOSFETs control in half-bridge, full-bridge, synchronous buck, synchronous
boost, and active clamp topologies. UCC27282-Q1 gate driver IC also has built-in bootstrap diode to help power
supply designers optimize PWB area and to help reduce bill of material cost in most applications. The driver has
an enable/disable functionality to be used in applications where driver needs to be enabled or disabled based
on fault condition in other parts of the circuit. Interlock functionality of the device is very useful in applications
where overall reliability of the system is of utmost criteria and redundant protection is desired. Each channel is
controlled by its respective input pins (HI and LI), allowing flexibility to control ON and OFF state of the output.
Both the outputs are forced OFF when the two inputs overlap.
Switching power devices such as MOSFETs have two main loss components; switching losses and conduction
losses. Conduction loss is dominated by current through the device and ON resistance of the device. Switching
losses are dominated by gate charge of the switching device, gate voltage of the switching device, and
switching frequency. Applications where operating switching frequency is very high, the switching losses start
to significantly impact overall system efficiency. In such applications, to reduce the switching losses it becomes
essential to reduce the gate voltage. The gate voltage is determined by the supply voltage the gate driver
ICs, therefore, the gate driver IC needs to operate at lower supply voltage in such applications. UCC27282-Q1
gate driver has typical UVLO level of 5V and therefore, they are perfectly suitable for such applications. There
is enough UVLO hysteresis provided to avoid any chattering or nuisance tripping which improves system
robustness.
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8.2 Typical Application
7V
75 V
EN
VDD
SECONDARY
SIDE
CIRCUIT
HB
HI
LI
CONTROL
PWM
CONTROLLER
DRIVE
HI
HO
HS
DRIVE
LO
LO
UCC27282
ISOLATION
AND
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Figure 8-1. Typical Application
8.2.1 Design Requirements
Table below lists the system parameters. UCC27282-Q1 needs to operate satisfactorily in conjunction with them.
Table 8-1. Design Requirements
Parameter
Value
MOSFET
CSD19535KTT
Maximum Bus/Input Voltage, Vin
75V
Operating Bias Votage, VDD
7V
Switching Frequency, Fsw
300kHz
Total Gate Charge of FET at given VDD, QG
52nC
MOSFET Internal Gate Resistance, RGFET_Int
1.4
Maximum Duty Cycle, DMax
0.5
Gate Driver
UCC27282-Q1
8.2.2 Detailed Design Procedure
8.2.2.1 Select Bootstrap and VDD Capacitor
The bootstrap capacitor must maintain the VHB-HS voltage above the UVLO threshold for normal operation.
Calculate the maximum allowable drop across the bootstrap capacitor, ΔVHB, with Equation 1.
¿VHB = VDD F VDH F VHBL
= :7 V 1 V (4.4 V 0.37 V); = 1.97 V
(1)
where
•
•
•
18
VDD is the supply voltage of gate driver device
VDH is the bootstrap diode forward voltage drop
VHBL is the HB falling threshold ( VHBR(max) – VHBH)
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In this example the allowed voltage drop across bootstrap capacitor is 1.97 V.
It is generally recommended that ripple voltage on both the bootstrap capacitor and VDD capacitor should be
minimized as much as possible. Many of commercial, industrial, and automotive applications use ripple value of
0.5 V.
Use Equation 2 to estimate the total charge needed per switching cycle from bootstrap capacitor.
DMAX
IHB
Q TOTAL = Q G + IHBS × l
p+l
p
fSW
fSW
= 52 nC + 0.083 nC + 1.33 nC = 53.41 nC
(2)
where
•
•
•
•
QG is the total MOSFET gate charge
IHBS is the HB to VSS leakage current from datasheet
DMax is the converter maximum duty cycle
IHB is the HB quiescent current from the datasheet
The caculated total charge is 53.41 nC.
Next, use Equation 3 to estimate the minimum bootstrap capacitor value.
CBOOT :min ; =
QTOTAL
53.41 nC
=
= 27.11 nF
¿VHB
1.97 V
(3)
The calculated value of minimum bootstrap capacitor is 27.11 nF. It should be noted that, this value of
capacitance is needed at full bias voltage. In practice, the value of the bootstrap capacitor must be greater
than calculated value to allow for situations where the power stage may skip pulse due to various transient
conditions. It is recommended to use a 100-nF bootstrap capacitor in this example. It is also recommenced to
include enough margin and place the bootstrap capacitor as close to the HB and HS pins as possible. Also
place a small size, 0402, low value, 1000 pF, capacitor to filter high frequency noise, in parallel with main bypass
capacitor.
For this application, choose a CBOOT capacitor that has the following specifications: 0.1 µF, 25 V, X7R
As a general rule the local VDD bypass capacitor must be greater than the value of bootstrap capacitor
value (generally 10 times the bootstrap capacitor value). For this application choose a CVDD capacitor with the
following specifications: 1 µF , 25 V, X7R
CVDD capacitor is placed across VDD and VSS pin of the gate driver. Similar to bootstrap capacitors, place a
small size and low value capacitor in parallel with the main bypass capacitor. For this application, choose 0402,
1000 pF, capacitance in parallel with main bypass capacitor to filter high frequency noise.
The bootstrap and bias capacitors must be ceramic types with X7R dielectric or better. Choose a capacitor with
a voltage rating at least twice the maximum voltage that it will be exposed to. Choose this value because most
ceramic capacitors lose significant capacitance when biased. This value also improves the long term reliability of
the system.
8.2.2.2 Estimate Driver Power Losses
The total power loss in gate driver device such as the UCC27282-Q1 is the summation of the power loss in
different functional blocks of the gate driver device. These power loss components are explained in this section.
1. Equation 4 describes how quiescent currents (IDD and IHB) affect the static power losses, PQC.
PQC = :VDD × IDD ; + :VDD F VDH ; × IHB
= 7 V × 0.4 mA + 6 V × 0.4 mA = 5.2 mW
(4)
it is not shown here, but for better approximation, add no load operating current, IDDO and IHBO in above
equation.
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2. Equation 5 shows how high-side to low-side leakage current (IHBS) affects level-shifter losses (PIHBS).
PIHBS = VHB × IHBS × D = 82 V × 50 µA × 0.5 = 2.05 mW
(5)
where
• D is the high-side MOSFET duty cycle
• VHB is the sum of input voltage and voltage across bootstrap capacitor.
3. Equation 6 shows how MOSFETs gate charge (QG) affects the dynamic losses, PQG.
R GD _R
R GD _R + R GATE + R GFET :int ;
= 2 × 7 V × 52 nC × 300 kHz × 0.74 = 0.16 W
PQG = 2 × VDD × Q G × fSW ×
(6)
where
•
•
•
•
•
QG is the total MOSFET gate charge
fSW is the switching frequency
RGD_R is the average value of pullup and pulldown resistor
RGATE is the external gate drive resistor
RGFET(int) is the power MOSFETs internal gate resistor
Assume there is no external gate resistor in this example. The average value of maximum pull-up and
pull down resistance of the driver output section is approximately 4 Ω. Substitute the application values to
calculate the dynamic loss due to gate charge, which is 160 mW here.
4. Equation 7 shows how parasitic level-shifter charge (QP) on each switching cycle affects dynamic losses,
(PLS) during high-side switching.
PLS = VHB × QP × fSW
(7)
For this example and simplicity, it is assumed that value of parasitic charge QP is 1 nC. Substituting values
results in 24.6 mW as level shifter dynamic loss. This estimate is very high for level shifter dynamic losses.
The sum of all the losses is 191.85 mW as a total gate driver loss. As shown in this example, in most
applications the dynamic loss due to gate charge dominates the total power loss in gate driver device. For
gate drivers that include bootstrap diode, one should also estimate losses in bootstrap diode. Diode forward
conduction loss is computed as product of average forward voltage drop and average forward current.
Equation 8 estimates the maximum allowable power loss of the device for a given ambient temperature.
PMAX =
kTJ F TA o
REJA
(8)
where
•
•
•
•
PMAX is the maximum allowed power dissipation in the gate driver device
TJ is the recommended maximum operating junction temperature
TA is hte ambient temperature of the gate driver device
RθJA is the junction-to-ambient thermal resistance
To better estimate the junction temperature of the gate driver device in the application, it is recommended to
first accurately measure the case temperature and then determine the power dissipation in a given application.
Then use ψJT to calculate junction temperature. After estimating junction temperature and measuring ambient
temperature in the application, calculate θJA(effective). Then, if design parameters (such as the value of an external
gate resistor or power MOSFET) change during the development of the project, use θJA(effective) to estimate how
these changes affect junction temperature of the gate driver device.
For detailed information regarding the thermal information table, please refer to the Semiconductor and Device
Package Thermal Metrics application report.
20
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8.2.2.3 Selecting External Gate Resistor
In high-frequency switching power supply applications where high-current gate drivers such as the UCC27282Q1 are used, parasitic inductances, parasitic capacitances and high-current loops can cause noise and ringing
on the gate of power MOSFETs. Often external gate resistors are used to damp this ringing and noise. In some
applications the gate charge, which is load on gate driver device, is significantly larger than gate driver peak
output current capability. In such applications external gate resistors can limit the peak output current of the
gate driver. it is recommended that there should be provision of external gate resistor whenever the layout or
application permits.
Use Equation 9 to calculate the driver high-side pull-up current.
IOHH =
VDD F VDH
R HOH + RGATE + RGFET:int;
(9)
where
•
•
•
•
•
IOHH is the high-side, peak pull-up current
VDH is the bootstrap diode forward voltage drop
RHOH is the gate driver internal high-side pull-up resistor. Value either directly provided in datasheet or can be
calculated from test conditions (RHOH = VHOH/IHO)
RGATE is the external gate resistance connected between driver output and power MOSFET gate
RGFET(int) is the MOSFET internal gate resistance provided by MOSFET datasheet
Use Equation 10 to calculate the driver high-side sink current.
IOLH =
VDD F VDH
R HOL + RGATE + RGFET:int;
(10)
where
•
RHOL is the gate driver internal high-side pull-down resistance
Use Equation 11 to calculate the driver low-side source current.
IOHL =
VDD
R LOH + RGATE + RGFET:int;
(11)
where
•
RLOH is the gate driver internal low-side pull-up resistance
Use Equation 12 to calculate the driver low-side sink current.
IOLL =
VDD
R LOL + RGATE + RGFET:int;
(12)
where
•
RLOL is the gate driver internal low-side pull-down resistance
Typical peak pull up and pull down current of the device is 2.5 A and 3.5 A respectively. These equations help
reduce the peak current if needed. To establish different rise time value compared to fall time value, external
gate resistor can be anti-paralleled with diode-resistor combination as shown in Figure 8-1. Generally selecting
an optimal value or configuration of external gate resistor is an iterative process. For additional information on
selecting external gate resistor please refer to External Gate Resistor Design Guide for Gate Drivers
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8.2.2.4 Delays and Pulse Width
The total delay encountered in the PWM, driver and power stage need to be considered for a number of
reasons, primarily delay in current limit response. Also to be considered are differences in delays between
the drivers which can lead to various concerns depending on the topology. The synchronous buck topology
switching requires careful selection of dead-time between the high-side and low-side switches to avoid cross
conduction as well as excessive body diode conduction.
Bridge topologies can be affected by a volt-second imbalance on the transformer if there is imbalance in
the high-side and low-side pulse widths in any operating condition. The UCC27282-Q1 device has maximum
propagation delay, across process, and temperature variation, of 30 ns and delay matching of 7 ns, which is one
of the best in the industry.
Narrow input pulse width performance is an important consideration in gate driver devices, because output may
not follow input signals satisfactorily when input pulse widths are very narrow. Although there may be relatively
wide steady state PWM output signals from controller, very narrow pulses may be encountered under following
operating conditions.
•
•
•
soft-start period
large load transients
short circuit conditions
These narrow pulses appear as an input signal to the gate driver device and the gate driver device need to
respond properly to these narrow signals.
Figure 8-2 shows that the UCC27282-Q1 device produces reliable output pulse even when the input pulses are
very narrow and bias voltages are very low. The propagation delay and delay matching do not get affected when
the input pulse width is very narrow.
HI (2V/div)
BW=1GHz
LI (2V/div)
BW=1GHz
HO (5V/div)
LO (5V/div)
BW=1GHz
BW=1GHz
Figure 8-2. Input and Output Pulse Width
8.2.2.5 External Bootstrap Diode
The UCC27282-Q1 incorporates the bootstrap diode necessary to generate the high-side bias for HO to
work satisfactorily. The characteristics of this diode are important to achieve efficient, reliable operation. The
characteristics to consider are forward voltage drop and dynamic resistance. Generally, low forward voltage drop
diodes are preferred for low power loss during charging of the bootstrap capacitor. The device has a boot diode
forward voltage drop rated at 0.85 V and dynamic resistance of 1.5 Ω for reliable charge transfer to the bootstrap
capacitor. The dynamic characteristics to consider are diode recovery time and stored charge. Diode recovery
times that are specified without operating conditions, can be misleading. Diode recovery times at no forward
current (IF) can be noticeably less than with forward current applied. The UCC27282-Q1 boot diode recovery is
specified as 50 ns at IF = 20 mA, IREV = 0.5 A. Dynamic impedance of UCC27282-Q1 bootstrap diode naturally
22
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limits the peak forward current and prevents any damage if repetitive peak forward current pulses exist in the
system for most applications.
In applications where switching frequencies are very high, for example in excess of 1 MHz, and the low-side
minimum pulse widths are very small, the diode peak forward current could be very high and peak reverse
current could also be very high, specifically if high bootstrap capacitor value has been chosen. In such
applications it might be advisable to use external Schottkey diode as bootstrap diode. It is safe to at least
make a provision for such diode on the board if possible.
8.2.2.6 VDD and Input Filter
Some switching power supply applications are extremely noisy. Noise may come from ground bouncing and
ringing at the inputs, (which are the HI and LI pins of the gate driver device). To mitigate such situations, the
UCC27282-Q1 offers both negative input voltage handling capability and wide input threshold hysteresis. If these
features are not enough, then the application might need an input filter. Small filter such as 10-Ω resistor and
47-pF capacitor might be sufficient to filter noise at the inputs of the gate driver device. This RC filter would
introduce delay and therefore need to be considered carefully. High frequency noise on bias supply can cause
problems in performance of the gate driver device. To filter this noise it is recommended to use 1-Ω resistor in
series with VDD pin as shown in Figure 8-1. This resistor also acts as a current limiting element. In the event of
short circuit on the bias rail, this resistor opens up and prevents further damage. This resistor can also be helpful
in debugging the design during development phase.
8.2.2.7 Transient Protection
As mentioned in previous sections, high power high switching frequency power supplies are inherently noisy.
High dV/dt and dI/dt in the circuit can cause negative voltage on different pins such as HO, LO, and HS. The
device tolerates negative voltage on all of these pins as mentioned in specification tables. If parasitic elements of
the circuit cause very large negative swings, circuit might require additional protection. In such cases fast acting
and low leakage type Schottky diode should be used. This diode must be placed as close to the gate driver
device pin as possible for it to be effective in clamping excessive negative voltage on the gate driver device pin.
Sometimes a small resistor, (for example 2 Ω, in series with HS pin) is also effective in improving performance
reliability. To avoid the possibility of driver device damage due to over-voltage on its output pins or supply pins,
low leakage Zener diode can be used. A 15-V Zener diode is often sufficient to clamp the voltage below the
maximum recommended value of 16 V.
8.2.3 Application Curves
To minimize the switching losses in power supplies, turn-ON and turn-OFF of the power MOSFETs need to
be as fast as possible. Higher the drive current capability of the driver, faster the switching. Therefore, the
UCC27282-Q1 is designed with high drive current capability and low resistance of the output stages. One of the
common way to test the drive capability of the gate driver device , is to test it under heavy load. Rise time and
fall time of the outputs would provide idea of drive capability of the gate driver device. There must not be any
resistance in this test circuit. HO Rise Time and HO Fall Time shows rise time and fall time of HO respectively of
UCC27282-Q1. Figure 8-5 and Figure 8-6 shows rise time and fall time of LO respectively of UCC27282-Q1. For
accuracy purpose, the VDD and HB pin of the gate driver device were connected together. HS and VSS pins are
also connected together for this test.
Peak current capability can be estimated using the fastest dV/dt along the rise and fall curve of the plot. This
method is also useful in comparing performance of two or more gate driver devices.
As explained in Section 8.2.2.4, propagation delay plays an important role in reliable operation of many
applications. Figure 8-7 and Figure 8-8
Figure 8-8 shows propagation delay and delay matching of UCC27282-Q1. In many switching power supply
applications input signals to the gate driver have large amplitude high frequency noise. If there is no filter
employed at the input, then there is a possibility of false signal passing through the gate driver and causing
shoot-through on the output. UCC27282-Q1 prevents such shoot-through. If two inputs are high at the same
time, UCC27282-Q1 shuts both the outputs off. Figure 8-9 shows interlock feature of UCC27282-Q1 and Figure
8-10 shows input negative voltage handling capability of UCC27282-Q1.
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VDD = VHB = 6 V, HS =
VSS
CLOAD = 10 nF
Ch4 = HO
VDD = VHB=6 V, HS =
VSS
Figure 8-3. HO Rise Time
A.
VDD = VHB = 6 V, HS = VSS
CLOAD = 10
nF
Ch4 = HO
Figure 8-4. HO Fall Time
CLOAD = 10 nF Ch4 = LO
Figure 8-5. LO Rise Time
A.
VDD = VHB = 6 V, HS =
VSS
CLOAD = 10 nF
Ch4 = LO
Figure 8-6. LO Fall Time
A.
VDD = 6 V
CLOAD = 2
nF
Ch1 = HI Ch2 = LI Ch3 = HO Ch4
= LO
Figure 8-7. Propagation Delay and Delay Matching
24
A.
VDD = 6 V
CLOAD = 2 nF
Ch1 = HI Ch2 = LI Ch3 = HO Ch4
= LO
Figure 8-8. Propagation Delay and Delay Matching
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HI (2V/div)
LI (2V/div)
HO (5V/div)
LO (5V/div)
A.VDD = VHB = 12 V, HS = VSS
CLOAD = 0 nF
Figure 8-9. Input Shoot-through Protection or
Interlock
A.
VDD = 10 V Vin =
100 V
CL = 1
nF
Ch1 = HI Ch2 = LI Ch3 = HO
Ch4 = LO
Figure 8-10. Input Negative Voltage
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9 Power Supply Recommendations
The recommended bias supply voltage range for UCC27282-Q1 is from 5.5 V to 16 V. The lower end of this
range is governed by the internal under voltage-lockout (UVLO) protection feature, 5 V typical, of the VDD supply
circuit block. The upper end of this range is driven by the 16-V recomended maximum voltage rating of the VDD.
It is recommended that voltage on VDD pin should be lower than maximum recommended voltage. In some
transient condition it is not possible to keep this voltage below recommended maximum level and therefore
absolute maximum voltage rating of the UCC27282-Q1 is 20 V.
The UVLO protection feature also involves a hysteresis function. This means that once the device is operating
in normal mode, if the VDD voltage drops, the device continues to operate in normal mode as far as the
voltage drop do not exceeds the hysteresis specification, VDDHYS. If the voltage drop is more than hysteresis
specification, the device shuts down. Therefore, while operating at or near the 5.5-V range, the voltage ripple on
the auxiliary power supply output should be smaller than the hysteresis specification of UCC27282-Q1 to avoid
triggering device shutdown.
A local bypass capacitor should be placed between the VDD and GND pins. This capacitor should be located
as close to the device as possible. A low ESR, ceramic surface mount capacitor is recommended. It is
recommended to use two capacitors across VDD and GND: a low capacitance ceramic surface-mount capacitor
for high frequency filtering placed very close to VDD and GND pin, and another high capacitance value surfacemount capacitor for device bias requirements. In a similar manner, the current pulses delivered by the HO pin
are sourced from the HB pin. Therefore, two capacitors across the HB to HS are recommended. One low value
small size capacitor for high frequency filtering and another one high capacitance value capacitor to deliver HO
pulses.
UCC27282-Q1 has enable/disable functionality through EN pin. Therefore, signal at the EN pin should be as
clean as possible. If EN pin is not used, then it is recommended to connect the pin to VDD pin. If EN pin is pulled
up through a resistor, then the pull-up resistor needs to be strong. In noise prone applications, it is recommended
to filter the EN pin with small capacitor, such as X7R 0402 1nF.
In power supplies where noise is very dominant and there is space on the PWB (Printed Wiring Board), it is
recommended to place a small RC filter at the inputs. This allows for improving the overall performance of
the design. In such applications. it is also recommended to have a place holder for power MOSFET external
gate resistor. This resistor allows the control of not only the drive capability but also the slew rate on HS,
which impacts the performance of the high-side circuit. If diode is used across the external gate resistor, it is
recommended to use a resistor in series with the diode, which provides further control of fall time.
In power supply applications such as motor drives, there exist lot of transients through-out the system. This
sometime causes over voltage and under voltage spikes on almost all pins of the gate driver device. To increase
the robustness of the design, it is recommended that the clamp diode should be used on HO and LO pins. If user
does not wish to use power MOSFET parasitic diode, external clamp diode on HS pin is recommended, which
needs to be high voltage high current type (same rating as MOSFET) and very fast acting. The leakage of these
diodes across the temperature needs to be minimal.
In power supply applications where it is almost certain that there is excessive negative HS voltage, it is
recommended to place a small resistor between the HS pin and the switch node. This resistance helps limit
current into the driver device up to some extent. This resistor will impact the high side drive capability and
therefore needs to be considered carefully.
26
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10 Layout
10.1 Layout Guidelines
To achieve optimum performance of high-side and low-side gate drivers, one must consider following printed
wiring board (PWB) layout guidelines.
•
•
•
•
•
•
Low ESR/ESL capacitors must be connected close to the device between VDD and VSS pins and between
HB and HS pins to support high peak currents drawn from VDD and HB pins during the turn-on of the
external MOSFETs.
To prevent large voltage transients at the drain of the top MOSFET, a low ESR electrolytic capacitor and a
good quality ceramic capacitor must be connected between the high side MOSFET drain and ground (VSS).
In order to avoid large negative transients on the switch node (HS) pin, the parasitic inductances between
the source of the high-side MOSFET and the source of the low-side MOSFET (synchronous rectifier) must be
minimized.
Overlapping of HS plane and ground (VSS) plane should be minimized as much as possible so that coupling
of switching noise into the ground plane is minimized.
Thermal pad should be connected to large heavy copper plane to improve the thermal performance of
the device. Generally it is connected to the ground plane which is the same as VSS of the device. It is
recommended to connect this pad to the VSS pin only.
Grounding considerations:
– The first priority in designing grounding connections is to confine the high peak currents that charge and
discharge the MOSFET gates to a minimal physical area. This confinement decreases the loop inductance
and minimize noise issues on the gate terminals of the MOSFETs. Place the gate driver as close to the
MOSFETs as possible.
– The second consideration is the high current path that includes the bootstrap capacitor, the bootstrap
diode, the local ground referenced bypass capacitor, and the low-side MOSFET body diode. The
bootstrap capacitor is recharged on a cycle-by-cycle basis through the bootstrap diode from the ground
referenced VDD bypass capacitor. The recharging occurs in a short time interval and involves high peak
current. Minimizing this loop length and area on the circuit board is important to ensure reliable operation.
10.2 Layout Example
VSS Plane
(Top and Bottom Layer)
To High Side MOSFET
Input Filters
(Top Layer)
Boot Diode & Capacitor
(Bottom Layer)
Input PWMs
To Low Side
MOSFET
VDD Capacitors
(Top Layer)
Figure 10-1. Layout Example
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11 Device and Documentation Support
11.1 Third-Party Products Disclaimer
TI'S PUBLICATION OF INFORMATION REGARDING THIRD-PARTY PRODUCTS OR SERVICES DOES NOT
CONSTITUTE AN ENDORSEMENT REGARDING THE SUITABILITY OF SUCH PRODUCTS OR SERVICES
OR A WARRANTY, REPRESENTATION OR ENDORSEMENT OF SUCH PRODUCTS OR SERVICES, EITHER
ALONE OR IN COMBINATION WITH ANY TI PRODUCT OR SERVICE.
11.2 Receiving Notification of Documentation Updates
To receive notification of documentation updates, navigate to the device product folder on ti.com. In the upper
right corner, click on Alert me to register and receive a weekly digest of any product information that has
changed. For change details, review the revision history included in any revised document.
11.3 Support Resources
TI E2E™ support forums are an engineer's go-to source for fast, verified answers and design help — straight
from the experts. Search existing answers or ask your own question to get the quick design help you need.
Linked content is provided "AS IS" by the respective contributors. They do not constitute TI specifications and do
not necessarily reflect TI's views; see TI's Terms of Use.
11.4 Trademarks
TI E2E™ is a trademark of Texas Instruments.
All trademarks are the property of their respective owners.
11.5 Electrostatic Discharge Caution
This integrated circuit can be damaged by ESD. Texas Instruments recommends that all integrated circuits be handled
with appropriate precautions. Failure to observe proper handling and installation procedures can cause damage.
ESD damage can range from subtle performance degradation to complete device failure. Precision integrated circuits may
be more susceptible to damage because very small parametric changes could cause the device not to meet its published
specifications.
11.6 Glossary
TI Glossary
28
This glossary lists and explains terms, acronyms, and definitions.
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Mechanical, Packaging, and Orderable Information
The following pages include mechanical, packaging, and orderable information. This information is the most
current data available for the designated devices. This data is subject to change without notice and revision of
this document. For browser-based versions of this data sheet, refer to the left-hand navigation.
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PACKAGE OPTION ADDENDUM
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30-Jul-2021
PACKAGING INFORMATION
Orderable Device
Status
(1)
Package Type Package Pins Package
Drawing
Qty
Eco Plan
(2)
Lead finish/
Ball material
MSL Peak Temp
Op Temp (°C)
Device Marking
(3)
(4/5)
(6)
UCC27282QDDAQ1
ACTIVE SO PowerPAD
DDA
8
75
RoHS & Green
NIPDAUAG
Level-2-260C-1 YEAR
125 to -40
27282Q
UCC27282QDDARQ1
ACTIVE SO PowerPAD
DDA
8
2500
RoHS & Green
NIPDAUAG
Level-2-260C-1 YEAR
125 to -40
27282Q
UCC27282QDQ1
ACTIVE
SOIC
D
8
75
RoHS & Green
NIPDAU
Level-2-260C-1 YEAR
-40 to 125
U282Q
UCC27282QDRCRQ1
ACTIVE
VSON
DRC
10
3000
RoHS & Green
NIPDAU
Level-2-260C-1 YEAR
-40 to 125
U282Q
UCC27282QDRCTQ1
ACTIVE
VSON
DRC
10
250
RoHS & Green
NIPDAU
Level-2-260C-1 YEAR
-40 to 125
U282Q
UCC27282QDRQ1
ACTIVE
SOIC
D
8
2500
RoHS & Green
NIPDAU
Level-2-260C-1 YEAR
-40 to 125
U282Q
(1)
The marketing status values are defined as follows:
ACTIVE: Product device recommended for new designs.
LIFEBUY: TI has announced that the device will be discontinued, and a lifetime-buy period is in effect.
NRND: Not recommended for new designs. Device is in production to support existing customers, but TI does not recommend using this part in a new design.
PREVIEW: Device has been announced but is not in production. Samples may or may not be available.
OBSOLETE: TI has discontinued the production of the device.
(2)
RoHS: TI defines "RoHS" to mean semiconductor products that are compliant with the current EU RoHS requirements for all 10 RoHS substances, including the requirement that RoHS substance
do not exceed 0.1% by weight in homogeneous materials. Where designed to be soldered at high temperatures, "RoHS" products are suitable for use in specified lead-free processes. TI may
reference these types of products as "Pb-Free".
RoHS Exempt: TI defines "RoHS Exempt" to mean products that contain lead but are compliant with EU RoHS pursuant to a specific EU RoHS exemption.
Green: TI defines "Green" to mean the content of Chlorine (Cl) and Bromine (Br) based flame retardants meet JS709B low halogen requirements of