TI UCC28950-Q1

UCC28950-Q1
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SLUSAG4A – APRIL 2011 – REVISED JULY 2012
Phase-Shifted Full-Bridge Controller With Synchronous Rectification
Check for Samples: UCC28950-Q1
FEATURES
1
•
•
•
•
•
•
•
•
•
Qualified for Automotive Applications
AEC-Q100 Qualified With the Following
Results:
– Device Temperature Grade 1: –40ºC to
125ºC Ambient Operating Temperature
Range
– Device HBM ESD Classification Level H2
– Device CDM ESD Classification Level C3B
Enhanced Wide-Range Resonant Zero-Voltage
Switching (ZVS) Capability
Direct Synchronous Rectifier (SR) Control
Light-Load Efficiency Management Including
– Burst Mode Operation
– Discontinuous Conduction Mode (DCM),
Dynamic SR On/Off Control With
Programmable Threshold
– Programmable Adaptive Delay
Average- or Peak-Current Mode Control With
Programmable Slope Compensation and
Voltage-Mode Control
Closed-Loop Soft-Start and Enable Function
Programmable Switching Frequency up to 1
MHz with Bidirectional Synchronization
(±3%) Cycle-by-Cycle Current Limit Protection
•
•
•
With Hiccup Mode Support
150-µA Start-Up Current
VDD Undervoltage Lockout
Wide Temperature Range, –40°C to 125°C
APPLICATIONS
•
•
•
•
Phase-Shifted Full-Bridge Converters
Industrial Power Systems
High-Density Power Architectures
Solar Inverters and Electric Vehicles
DESCRIPTION
The
UCC28950-Q1
enhanced
phase-shifted
controller builds upon Texas Instruments' industrystandard UCCx895 phase-shifted controller family
with enhancements that offer best-in-class efficiency
in today’s high-performance power systems. The
UCC28950-Q1 implements advanced control of the
full bridge along with active control of the
synchronous-rectifier output stage.
The primary-side signals allow programmable delays
to ensure ZVS operation over wide load-current and
input-voltage ranges, while the load current naturally
tunes the secondary-side switching delays of the
synchronous rectifiers, maximizing overall system
efficiency.
1
Please be aware that an important notice concerning availability, standard warranty, and use in critical applications of
Texas Instruments semiconductor products and disclaimers thereto appears at the end of this data sheet.
PRODUCTION DATA information is current as of publication date.
Products conform to specifications per the terms of the Texas
Instruments standard warranty. Production processing does not
necessarily include testing of all parameters.
Copyright © 2011–2012, Texas Instruments Incorporated
UCC28950-Q1
SLUSAG4A – APRIL 2011 – REVISED JULY 2012
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UCC28950-Q1 Typical Application
+
CT
VS
CREF
-
UCC28950
R1
R2
1
VREF
GND 24
2
EA+
VDD 23
3
EA-
OUTA 22
CVDD
R3
VSENSE
C1
R5
C2
R6 R4 C3
ENABLE
4
COMP
OUTB 21
B
CSS
5
SS/EN
OUTC 20
C
RAB
6
DELAB
OUTD 19
D
RCD
7
DELCD
OUTE 18
E
REF
8
DELEF
OUTF 17
F
9
TMIN
SYNC 16
SYNC
RA(hi)
RTMIN
RT
VREF
10 RT
RSUM
11 RSUM
VREF
R7
12 DCM
VDD
A
VDD
QA
QC
QB
QD
VDD
B
C
VDD
D
VOUT
+
CS 15
ADEL 14
RDCM(hi)
Voltage Current
Sense
VDD
A
RAEF(hi)
E
UCC27324
QE
UCC27324
QF
F
ADELEF 13
-
RA
RCS
RDCM
RAEF
VSENSE
2
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These devices have limited built-in ESD protection. The leads should be shorted together or the device placed in conductive foam
during storage or handling to prevent electrostatic damage to the MOS gates.
DESCRIPTION (CONT.)
The UCC28950-Q1 also offers multiple light-load management features, including burst mode and dynamic SR
on/off control when transitioning in and out of discontinuous-current-mode (DCM) operation, ensuring ZVS
operation is extended down to much lighter loads.
In addition, the UCC28950-Q1 includes support for peak current along with voltage-mode control, programmable
switching frequency up to 1 MHz, and a wide set of protection features including cycle-by-cycle current limit,
UVLO, and thermal shutdown. It is easy to arrange 90-degree phase-shifted interleaved synchronized operation
between two converters.
The UCC28950-Q1 is available in a TSSOP-24 package.
ORDERING INFORMATION
TA
PACKAGE
ORDERABLE PART NUMBER
TOP-SIDE MARKING
–40°C to 105°C
TSSOP (PW)
Reel of 2000
UCC28950TPWRQ1
UCC28950Q
–40°C to 125°C
TSSOP (PW)
Reel of 2000
UCC28950QPWRQ1
U28950Q
ABSOLUTE MAXIMUM RATINGS
over operating free-air temperature range (unless otherwise noted)
(1) (2)
PARAMETER
Input supply voltage range, VDD
(3)
VALUE
UNIT
–0.4 to 20
OUTA, OUTB, OUTC, OUTD, OUTE, OUTF
–0.4 to VDD + 0.4
Inputs voltages on DELAB, DELCD, DELEF, SS/EN, DCM, TMIN, RT, SYNC, RSUM, EA+, EA–,
COMP, CS, ADEL, ADELEF
–0.4 to VREF + 0.4
Output voltage on VREF
V
–0.4 to 5.6
Continuous total power dissipation
See dissipation rating table
Operating virtual junction temperature range, TJ
–40 to 150
°C
Storage temperature, Tstg
–65 to 150
°C
(1)
(2)
(3)
Stresses beyond those listed under Absolute Maximum Ratings may cause permanent damage to the device. These are stress ratings
only, and functional operation of the device at these or any other conditions beyond those indicated under Recommended Operating
Conditions is not implied. Exposure to absolute-maximum-rated conditions for extended periods may affect device reliability.
These devices are sensitive to electrostatic discharge; follow proper device handling procedures.
All voltages are with respect to GND unless otherwise noted. Currents are positive into, negative out of the specified terminal. See the
Package Options Addendum of the data sheet for thermal limitations and considerations of packages.
THERMAL INFORMATION
UCC28950-Q1
THERMAL METRIC (1)
PW
UNIT
24 PINS
θJA
Junction-to-ambient thermal resistance
93.3
°C/W
θJCtop
Junction-to-case (top) thermal resistance
24.2
°C/W
θJB
Junction-to-board thermal resistance
47.9
°C/W
ψJT
Junction-to-top characterization parameter
0.7
°C/W
ψJB
Junction-to-board characterization parameter
47.4
°C/W
(1)
For more information about traditional and new thermal metrics, see the IC Package Thermal Metrics application report, SPRA953.
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RECOMMENDED OPERATING CONDITIONS
over operating free-air temperature range (unless otherwise noted)
MIN
TYP
Supply voltage range, VDD
8
MAX
17
V
-40
125
°C
Converter switching frequency setting range, fSW(nom)
50
1000
kHz
Programmable delay range between OUTA, OUTB and OUTC, OUTD set by
resistors DELAB and DELCD and parameter KA (1)
30
1000
Programmable delay range between OUTA, OUTF and OUTB, OUTE set by
resistor DELEF, and parameter KEF (1)
30
1400
Programmable DCM range as percentage of voltage at CS (1)
5%
30%
Programmable tMIN range
100
800
Operating ambient temperature range
(1)
12
UNIT
ns
ns
Verified during characterization only.
ELECTRICAL CHARACTERISTICS (1)
VDD = 12 V, TA = –40°C to 125°C, CVDD = 1 µF, CREF = 1 µF, RAB = 22.6 kΩ, RCD = 22.6 kΩ , REF = 13.3 kΩ, RSUM = 124 kΩ,
RMIN = 88.7 kΩ, RT = 59 kΩ connected between RT pin and 5-V voltage supply to set fSW = 100 kHz (fOSC = 200 kHz) (unless
otherwise noted). All component designations are from the Typical Application Diagram, Figure 2.
PARAMETER
TEST CONDITION
MIN
TYP
MAX
UNITS
Under Voltage Lockout (UVLO)
UVLO_R
Start threshold
TH
6.75
7.3
7.9
UVLO_F
TH
6.15
6.7
7.2
0.53
0.6
0.75
150
270
µA
5
10
mA
5
5.075
Minimum operating voltage
after start
UVLO_H
Hysteresis
YST
V
Supply Currents
IDD(off)
Startup current
IDD
Operating supply current
VDD is 5.2 V
VREF Output Voltage
VREF
VREF total output range
0 ≤ IR ≤ 20 mA; VDD = from 8 V to 17 V
ISCC
Short-circuit current
VREF = 0 V
4.925
–53
V
–23
mA
KHz
Switching Frequency (½ of internal oscillator frequency fOSC)
fSW(nom)
Total range
DMAX
Maximum duty cycle
92
100
108
95%
97%
Synchronization
PHSYNC
Total range
RT = 59 kΩ between RT and GND; Input pulses
200 kHz, D = 0.5 at SYNC
85
90
95
°PH
fSYNC
Total range
RT = 59 kΩ between RT and 5 V; –40 °C ≤ TA ≤
125°C
180
200
220
kHz
tPW
Pulse duration
2.2
2.5
2.8
µs
(1)
4
Typical values for TA = 25°C
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ELECTRICAL CHARACTERISTICS(1) (continued)
VDD = 12 V, TA = –40°C to 125°C, CVDD = 1 µF, CREF = 1 µF, RAB = 22.6 kΩ, RCD = 22.6 kΩ , REF = 13.3 kΩ, RSUM = 124 kΩ,
RMIN = 88.7 kΩ, RT = 59 kΩ connected between RT pin and 5-V voltage supply to set fSW = 100 kHz (fOSC = 200 kHz) (unless
otherwise noted). All component designations are from the Typical Application Diagram, Figure 2.
PARAMETER
TEST CONDITION
MIN
TYP
MAX
UNITS
Error Amplifier
VICM range ensures parameters, the functionality
ensured for 3.6 V < VICM < VREF + 0.4 V, and –0.4
V < VICM < 0.5 V
VICM
Common mode input voltage
range
VIO
IBIAS
EAHIGH
High-level output voltage
(EA+) – (EA–) = 500 mV, IEAOUT = –0.5 mA
EALOW
Low-level output voltage
(EA+) – (EA–) = –500 mV, IEAOUT = 0.5 mA
ISOURCE
Error-amplifier source current
ISINK
Error-amplifier sink current
IVOL
Open-loop dc gain
GBW
Unity gain bandwidth (2)
0.5
3.6
Offset voltage
–7
7
mV
Input bias current
–1
1
µA
3.9
4.25
0.25
0.35
–8
–3.75
–0.5
2.7
4.6
5.75
100
V
V
mA
dB
3
MHz
Cycle-by-Cycle Current Limit
VCS_LIM
CS pin cycle-by-cycle
threshold
TCS
Propagation delay from CS to
OUTC and OUTD outputs
1.94
Input pulse between CS and GND from zero to 2.5
V
2
2.06
100
V
ns
Internal Hiccup Mode Settings
IDS
Discharge current to set cycleCS = 2.5 V, VSS = 4 V
by-cycle current limit duration
15
20
25
µA
VHCC
Hiccup off-time threshold
3.2
3.6
4.2
V
IHCC
Discharge current to set
hiccup-mode off-time
1.9
2.55
3.2
µA
20
25
30
µA
0.25
0.5
0.7
Soft Start/Enable
ISS
Charge current
VSS_STD
Shutdown/restart/reset
threshold
VSS_PU
Pullup threshold
3.3
3.7
4.3
VSS_CL
Clamp voltage
4.2
4.65
4.95
(2)
VSS = 0 V
V
Verified during characterization only.
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ELECTRICAL CHARACTERISTICS(1) (continued)
VDD = 12 V, TA = –40°C to 125°C, CVDD = 1 µF, CREF = 1 µF, RAB = 22.6 kΩ, RCD = 22.6 kΩ , REF = 13.3 kΩ, RSUM = 124 kΩ,
RMIN = 88.7 kΩ, RT = 59 kΩ connected between RT pin and 5-V voltage supply to set fSW = 100 kHz (fOSC = 200 kHz) (unless
otherwise noted). All component designations are from the Typical Application Diagram, Figure 2.
PARAMETER
TEST CONDITION
MIN
TYP
MAX
UNITS
Programmable Delay Time Set Accuracy and Range (3) (4) (5) (6) (7)
tABSET1
Short delay time set accuracy
between OUTA and OUTB
CS = ADEL = ADELEF = 1.8 V
32
45
56
ns
tABSET2
Long delay time set accuracy
between OUTA and OUTB
CS = ADEL = ADELEF = 0.2 V
216
270
325
ns
tCDSET1
Short delay time set accuracy
between OUTC and OUTD
CS = ADEL = ADELEF = 1.8 V
32
45
56
ns
tCDSET2
Long delay time set accuracy
between OUTC and OUTD
CS = ADEL = ADELEF = 0.2 V
216
270
325
ns
tAFSET1
Short delay time set accuracy
between falling OUTA, OUTF
CS = ADEL = ADELEF = 0.2 V
22
35
48
ns
tAFSET2
Long delay time set accuracy
between falling OUTA, OUTF
CS = ADEL = ADELEF = 1.8 V
190
240
290
ns
tBESET1
Short delay time set accuracy
between falling OUTB, OUTE
CS = ADEL = ADELEF = 0.2 V
22
35
48
ns
tBESET2
Long delay time set accuracy
between falling OUTB, OUTE
CS = ADEL = ADELEF = 1.8 V
190
240
290
ns
ΔtADBC
Pulse matching between
OUTA rise, OUTD fall and
OUTB rise, OUTC fall
CS = ADEL = ADELEF = 1.8 V, COMP = 2 V
-50
0
50
ns
ΔtABBA
Half cycle matching between
OUTA rise, OUTB rise and
OUTB rise, OUTA rise
CS = ADEL = ADELEF = 1.8 V, COMP = 2 V
-50
0
50
ns
ΔtEEFF
Pulse matching between
OUTE fall, OUTE rise and
OUTF fall, OUTF rise
CS = ADEL = ADELEF = 0.2 V, COMP = 2 V
-60
0
60
ns
ΔtEFFE
Pulse matching between
OUTE fall, OUTF rise and
OUTF fall, OUTE rise
CS = ADEL = ADELEF = 0.2 V, COMP = 2 V
-60
0
60
ns
(3)
(4)
(5)
(6)
(7)
6
See Figure 6 for timing diagram and tABSET1, tABSET2, tCDSET1, tCDSET2 definitions.
See Figure 9 for timing diagram and tAFSET1, tAFSET2, tBESET1, tBESET2 definitions.
Pair of outputs OUTC, OUTE and OUTD, OUTF always going high simultaneously.
Outputs A or B are never allowed to go high if both outputs OUTE and OUTF are high.
All delay settings are measured relatively 50% of pulse amplitude.
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ELECTRICAL CHARACTERISTICS(1) (continued)
VDD = 12 V, TA = –40°C to 125°C, CVDD = 1 µF, CREF = 1 µF, RAB = 22.6 kΩ, RCD = 22.6 kΩ , REF = 13.3 kΩ, RSUM = 124 kΩ,
RMIN = 88.7 kΩ, RT = 59 kΩ connected between RT pin and 5-V voltage supply to set fSW = 100 kHz (fOSC = 200 kHz) (unless
otherwise noted). All component designations are from the Typical Application Diagram, Figure 2.
PARAMETER
TEST CONDITION
MIN
TYP
MAX
UNITS
Light-Load Efficiency Circuit
DCM threshold, T = 25°C
VDCM = 0.4 V, Sweep CS confirm there are OUTE
and OUTF pulses
0.37
0.39
0.41
DCM threshold, T = 0°C to
85°C (8)
VDCM = 0.4 V, Sweep CS, confirm there are OUTE
and OUTF pulses
0.364
0.390
0.416
DCM threshold, T= –40°C to
125°C (8)
VDCM = 0.4 V, Sweep CS, confirm there are OUTE
and OUTF pulses
0.35
0.39
0.43
IDCM,SRC
DCM sourcing current
CS < DCM threshold
tMIN
Total range
RTMIN = 88.7 kΩ
VDCM
V
14
20
26
µA
425
525
625
ns
OUTPUTS OUTA, OUTB, OUTC, OUTD, OUTE, OUTF
ISINK/SRC
Sink/Source peak current (8)
tr
Rise time
CLOAD = 100 pF
9
25
ns
tf
Fall time
CLOAD = 100 pF
7
25
ns
RSRC
Output source resistance
IOUT = 20 mA
10
20
35
Ω
RSINK
Output sink resistance
IOUT = 20 mA
5
10
30
Ω
0.2
A
THERMAL SHUTDOWN
Rising threshold (8)
160
°C
Falling threshold (8)
140
°C
20
°C
Hysteresis
(8)
Verified during characterization only
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DEVICE INFORMATION
Plastic 24-pin TSSOP (PW)
UCC28950
1
VREF
GND 24
2
EA+
VDD 23
3
EA-
OUTA 22
4
COMP
OUTB 21
5
SS/EN
OUTC 20
6
DELAB
OUTD 19
7
DELCD
OUTE 18
8
DELEF
OUTF 17
9
TMIN
SYNC 16
10 RT
CS 15
11 RSUM
12 DCM
ADEL 14
ADELEF 13
PIN FUNCTIONS
PIN
8
I/O
FUNCTION
NUMBER
NAME
1
VREF
O
5-V, ±1.5%, 20-mA reference voltage output
2
EA+
I
Error amplifier non-inverting input
3
EA–
I
Error amplifier inverting input
4
COMP
I/O
5
SS/EN
I
Soft-start programming, device enable and hiccup-mode protection circuit
6
DELAB
I
Dead-time delay programming between OUTA and OUTB
7
DELCD
I
Dead-time delay programming between OUTC and OUTD
8
DELEF
I
Delay-time programming between OUTA to OUTF, and OUTB to OUTE
9
TMIN
I
Minimum duty-cycle programming in burst mode
10
RT
I
Oscillator frequency set. Master- or slave-mode setting
11
RSUM
I
Slope compensation programming. Voltage-mode or peak-current-mode setting
12
DCM
I
DCM threshold setting
13
ADELEF
I
Delay-time programming between primary-side and secondary-side switches, tAFSET
and tBESET.
14
ADEL
I
Dead-time programming for the primary switches over CS voltage range, tABSET and
tCDSET.
15
CS
I
Current sense for cycle-by-cycle overcurrent protection and adaptive delay functions
16
SYNC
I/O
Synchronization out from master controller to input of slave controller
17
OUTF
O
0.2-A sink/source synchronous switching output
18
OUTE
O
0.2-A sink/source synchronous switching output
19
OUTD
O
0.2-A sink/source primary switching output
20
OUTC
O
0.2-A sink/source primary switching output
21
OUTB
O
0.2-A sink/source primary switching output
22
OUTA
O
0.2-A sink/source primary switching output
23
VDD
I
Bias supply input
24
GND
Error amplifier output and input to the PWM comparator
Ground. All signals are referenced to this node.
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ADEL
14
VDD
UVLO
COMP
VDD
Thermal
Shutdown
VDD 23
EN
+
+ 7.3 V Rise
- 6.7 V Fall
VREF
1
COMP
4
EA-
3
EA+
2
22 OUTA
Reference
Generator
VDD
ON/OFF
5V LDO
+
+
+
Programmable
Delay CD
CLK
7
DELCD
19 OUTD
Oscillator
RAMP 2.8 V
0.8 V
RSUM 11
DELAB
20 OUTC
PWM
COMP
Lower "+" Input
is Dominant
6
21 OUTB
Logic Block
RT 10
Programmable
Delay AB
13 ADELEF
Ramp
Summing
18 OUTE
+
CS
Cycle-by-Cycle
ILIM
CS 15
Synchronization
Block
+
-
Programmable
Delay EF
DELEF
CS
Light-Load
Efficiency Block
2V
8
Soft Stat and Enable
with 0.55 V Threshold
16
24
12
9
5
SYNC
GND
DCM
TMIN
SS/EN
17 OUTF
Figure 1. Functional Block Diagram
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+
CT
VS
CREF
-
R1
UCC28950
R2
1
VREF
GND 24
2
EA+
VDD 23
3
EA-
OUTA 22
CVDD
R3
VSENSE
C1
R5
C2
R6 R4 C3
ENABLE
RT
4
COMP
OUTB 21
B
CSS
5
SS/EN
OUTC 20
C
RAB
6
DELAB
OUTD 19
D
RCD
7
DELCD
OUTE 18
E
REF
8
DELEF
OUTF 17
F
RTMIN
9
TMIN
SYNC 16
SYNC
RA(hi)
VREF
10 RT
RSUM
11 RSUM
R7
VREF
12 DCM
VDD
A
VDD
QA
QC
QB
QD
VDD
B
C
VDD
D
VOUT
+
CS 15
ADEL 14
RDCM(hi)
Voltage Current
Sense
VDD
A
RAEF(hi)
E
UCC27324
QE
UCC27324
QF
F
ADELEF 13
-
RA
RCS
RDCM
RAEF
VSENSE
Figure 2. Typical Application Diagram
10
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Start-Up Timing Diagram
No output delay shown, COMP-to-RAMP offset not included
2 VP-P
F
E
D
C
B
A
TMIN
COMP
RAMP
PWM
Add 0.85 V offset to RAMP
No PWM pulses shorter than TMIN
except during cycle-by-cycle current limit
PWM
TMIN
SS > 0.5 V, then release COMP, DCM, CS , Outputs A,B,C,D,E and F
CLK
TMIN
4.8-V rise, 4.6-V fall
VREF
VREF_GOOD
VDD 7.3-V rise, 6.7-V fall
VDD_GOOD
Burst Mode at the beginning of
start up until PWM> TMIN pulses
Figure 3.
Figure 4. UCC28950-Q1 Timing Diagram
NOTE
There is no pulse on OUTE during burst mode at start-up. Enabling the synchronous
rectifier outputs requires two preceding falling-edge PWM pulses.
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Steady State/Shutdown Timing Diagram
No output delay shown, COMP-to-RAMP offset not included
VDD failed and VDD_GOOD goes low,
Everything is shutdown
7.3V rise, 6.7V fall
VDD
VDD_GOOD
4.8V rise, 4.6V fall
VREF
VREF_GOOD
TMIN
CLK
TMIN
Add 0.85V offset to RAMP
COMP
2Vp-p
RAMP
PWM
No PWM pulses shorter than TMIN except
during cycle-by-cycle current limit
A
B
C
D
E
F
Figure 5. UCC28950-Q1 Timing Diagram
12
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DETAILED PIN DESCRIPTION AND PARAMETER SETTINGS
Start-Up Protection Logic
Before the UCC28950-Q1 controller starts up, there is a requirement to meet the following conditions:
• VDD voltage exceeds rising UVLO threshold, 7.3 V typical.
• The 5-V reference voltage is available.
• Junction temperature is below the thermal shutdown threshold of 140°C.
• The voltage on the soft-start capacitor is not below 0.55 V typical.
Meeting all those conditions causes the generation of an internal enable signal EN that initiates the soft-start
process. The voltage at the SS pin defines the duty cycle during the soft start, and cannot be lower than the duty
cycle set by TMIN, or by the cycle-by-cycle current-limit circuit, depending on load conditions.
Voltage Reference (VREF)
The accurate (±1.5%) 5-V reference voltage regulator with the short-circuit protection circuit supplies internal
circuitry and provides up to a 20-mA external output current for setting dc-dc converter parameters. Place a lowESR and -ESL decoupling capacitor CREF in the 1-µF to 2.2-µF range, preferably ceramic, from this pin to GND,
as close to the related pins as possible for best performance. The only condition where the reference regulator is
shut down internally is during undervoltage lockout.
Error Amplifier (EA+, EA–, COMP)
The error amplifier has two uncommitted inputs, EA+ and EA–, with a 3-MHz unity bandwidth, which allows
flexibility in closing the feedback loop. EA+ is a non-inverting input, EA– is an inverting input, and COMP is the
output of the error amplifier. The input-voltage common-mode range within which the parameters of the error
amplifier are specified is from 0.5 V to 3.6 V. The output of the error amplifier connects internally to the noninverting input of the PWM comparator. The range of the error-amplifier output of 0.25 V to 4.25 V far exceeds
the PWM comparator input-ramp signal range, which is from 0.8 V to 2.8 V. The soft-start signal serves as an
additional non-inverting input of the error amplifier. The lower of the two non-inverting inputs of the error amplifier
is the dominant input and sets the duty cycle where the output signal of the error amplifier is compared with the
internal ramp at the inputs of the PWM comparator.
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Soft Start and Enable (SS/EN)
The soft-start pin SS/EN is a multi-function pin used for the following operations:
• Closed-loop soft start with the gradual duty-cycle increase from the minimum set by TMIN up to the steadystate duty cycle required by the regulated output voltage
• Setting hiccup-mode conditions during cycle-by-cycle overcurrent limit
• On/off control for the converter
During soft start, one of the voltages at the SS/EN or EA+ pins, whichever is lower (SS/EN – 0.55 V) or EA+
voltage (see the Block Diagram), sets the reference voltage for a closed feedback loop. Both SS/EN and EA+
signals are non-inverting inputs of the error amplifier, with the COMP pin being its output. Thus the soft start
always goes under the closed feedback loop and the voltage at the COMP pin sets the duty cycle. The duty
cycle defined by the COMP voltage cannot be shorter than the TMIN pulse set by the user. However, if the cycleby-cycle current limit circuit sets the shortest duty cycle, then that duty cycle becomes dominant over the duty
cycle defined by the COMP voltage or by the TMIN block.
An external capacitor CSS, connected between SS/EN pin and ground, defines the soft-start duration and the
internal charge current that has typical value of 25 µA. Pulling the soft-start pin externally below 0.55 V shuts
down the controller. The release of the soft-start pin enables the controller to start, and if there is no current-limit
condition, the duty cycle applied to the output inductor gradually increases until it reaches the steady-state duty
cycle defined by the regulated output voltage of the converter. This happens when the voltage at the SS/EN pin
reaches and then exceeds the voltage at the EA+ pin, V(SS/EN) ≥ VNI / 0.55 V. Thus, for the given soft-start
time tSS, Equation 1 or Equation 2 can define the CSS value:
CSS(master ) =
CSS(slave) =
TSS ´ 25 mA
(VNI + 0.55 )
(1)
TSS
20.6
æ
ö
825K ´ Ln ç
÷
è 20.6 - VNI - 0.55 ø
(2)
For example, in Equation 1, if the user selects soft-start time TSS to be 10 ms, and the VNI is 2.5 V, then the softstart capacitor CSS is equal to 82 nF.
NOTE
For a converter configured in slave mode, make sure to place an 825-kΩ resistor from the
SS pin to ground.
Light-Load Power-Saving Mode
The UCD28950 offers four different light-load management techniques for improving the efficiency of a power
converter over a wide load-current range.
1. Adaptive delay,
(a) ADEL, which sets and optimizes the dead-time control for the primary switches over a wide load-current
range.
(b) ADELEF, which sets and optimizes the delay-time control between the primary-side switches and the
secondary-side switches.
2. TMIN, sets the minimum duty cycle as long as the part is not in current-limit mode.
3. Dynamic synchronous rectifier on/off control in DCM mode, for increased efficiency at light loads. The DCM
mode starts when the voltage at CS pin is lower than the threshold set by the user. In DCM mode, the device
pulls the synchronous output drive signals OUTE and OUTF low.
4. Burst mode, for maximum efficiency at very light loads or no load. Burst mode has an even number of PWM
TMIN pulses followed by off-time. The TMIN duration set by the user defines transition to the burst mode.
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Adaptive Delay, (Delay between OUTA and OUTB, OUTC and OUTD (DELAB, DELCD, ADEL))
The resistor RAB from the DELAB pin, DELAB to GND, along with the resistor divider RAHI from the CS pin to the
ADEL pin and RA from the ADEL pin to GND sets the delay TABSET between one of outputs OUTA or OUTB
going low and another output going high Figure 6.
OUTA
(OUTC)
TABSET2
TABSET2
TCDSET2
TCDSET2
TABSET1
TABSET1
TCDSET1
TCDSET1
OUTB
(OUTD)
Figure 6. Delay Definitions Between OUTA and OUTB, OUTC and OUTD
This delay gradually increases as a function of the CS signal from TABSET1, which is measured at VCS = 1.8 V, to
TABSET2, which is measured at VCS = 0.2 V. This approach ensures there is no shoot-through current during the
high-side and low-side MOSFET switching and optimizes the delay for the ZVS condition over a wide loadcurrent range. The resistor divider RAHI and RA determines the setting of the proportional ratio between longest
and shortest. Tying the CS and ADEL pins together achieves the maximum ratio. Connecting ADEL to GND fixes
the delay, which is then defined only by the resistor RAB from DELAB to GND. The delay TCDSET1 and TCDSET2
settings and their behavior for outputs OUTC and OUTD are very similar to the one described for OUTA and
OUTB. The difference is that resistor RCD connected between the DELCD pin and GND sets the delay TCDSET.
Delays for outputs OUTC and OUTD share with the outputs OUTA and OUTB the same CS voltage-dependence
pin ADEL.
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The following Equation 3 defines the delay time TABSET .
æ
ö
5 ´ R AB
TABSET = ç
÷ ns + 5ns
è 0.15 V + CS ´ K A ´ 1.46 ø
(3)
The same equation defines the delay time TCDSET in another leg, except RCD replaces RAB.
æ
ö
5 ´ RCD
TCDSET = ç
÷ ns + 5ns
è 0.15 V + CS ´ K A ´ 1.46 ø
(4)
In these equations RAB and RCD are in kΩ and CS, the voltage at pin CS, is in volts, and KA is a numerical
coefficient in the range from 0 to 1. The delay time TABSET and TCDSET are in ns. These equations are empirical
approximations derived from measured data. Thus, there is no unit agreement in the equations. As an example,
assume RAB = 15 kΩ, CS = 1 V and KA = 0.5. Then TABSET is 90.25 ns. In both Equation 3 and Equation 4, KA is
the same, defined as:
KA =
RA
R A + R AHI
(5)
KA sets how the delay is sensitive to CS voltage variation. If KA = 0 (ADEL shorted to GND), the delay is fixed. If
KA = 1 (ADEL is tied to CS), the delay is maximum at CS = 0.2 V and gradually decreases when CS goes up to
1.8 V. The ratio between the maximum and minimum delay can be up to 6:1.
TI recommends to start by setting KA = 0 and setting TABSET and TCDSET relatively large, using equations or plots
in the data sheet to avoid hard switching or even shoot-through current. Accordingly, resistors RAB and RCS set
the delay between outputs A, B and C, D. Program the optimal delays at light load first. Then by changing KA, set
the optimal delay for the outputs A, B at maximum current. KA for outputs C, D is the same as for A,D. Usually
outputs C and D have ZVS if sufficient delay is provided.
NOTE
The allowed resistor range on DELAB and DELCD, RAB and RCD is 13 kΩ to 90 kΩ.
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RA and RAHI define the portion of voltage at pin CS applied to the pin ADEL (See the Typical Application
Diagram, Figure 2). KA defines how significantly the delay time depends on CS voltage. KA varies from 0, where
ADEL pin is shorted to ground (RA = 0) and the delay does not depend on CS voltage, to 1, where ADEL ties to
CS (RAH = 0). Setting KA, RAB, and RCD provides the ability to maintain optimal ZVS conditions of primary
switches over load current, because the voltage at CS pin includes reflected load current to the primary side
through the current-sensing circuit. The plots in Figure 7 and Figure 8 show the delay-time settings as a function
of the CS voltage and KA for two different conditions: RAB = RCD = 13 kΩ (Figure 7) and RAB = RCD = 90 kΩ
(Figure 8 ).
TIME DELAY (RAB = RCD = 13 kW)
vs
CS VOLTAGE
350
TABSET, TCDSET - Time Delay - ns
300
250
KA = 0.0
KA = 0.1
200
KA = 0.25
KA = 0.50
150
KA = 0.75
KA = 1.0
100
50
5
0.0
0.2
0.4
0.6
0.8
1.0 1.2
1.4
1.6
1.8 2.0
CS Voltage - V
Figure 7. Delay-Time Set tABSET and tCDSET
(Over CS Voltage Variation and Selected KA for RAB and RCD Equal 13 kΩ)
TIME DELAY (RAB = RCD = 90 kW)
vs
CS VOLTAGE
2000
TABSET, TCDSET - Time Delay - ns
1800
1600
1400
KA = 0.0
1200
KA = 0.1
1000
KA = 0.50
KA = 0.25
KA = 0.75
800
KA = 1.0
600
400
200
0
0.0
0.2
0.4
0.6
0.8
1.0 1.2
1.4
1.6
1.8 2.0
CS Voltage - V
Figure 8. Delay-Time Set tABSET and tCDSET
(Over CS Voltage Variation and Selected KA for RAB and RCD Equal 90 kΩ)
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Adaptive Delay (Delay Between OUTA and OUTF, OUTB and OUTE (DELEF, ADELEF))
Resistor REF from the DELEF pin to GND along with resistor divider RAEFHI from the CS pin to the ADELEF pin
and RAEF from the ADELEF pin to GND sets equal delays tAFSET and tBESET between outputs OUTA or OUTB
going low and related output OUTF or OUTE going low Figure 9.
OUTA
(OUTB)
OUTD
(OUTC)
TAFSET1
TBESET1
OUTF
(OUTE)
TAFSET2
TBESET2
Figure 9. Delay Definitions Between OUTA and OUTF, OUTB and OUTE
These delays gradually increase as a function of the CS signal from tAFSET1, measured at VCS = 0.2 V, to TAFSET2,
measured at VCS = 1.8 V. Opposite to the DELAB and DELCD behavior, this delay is longest (TAFSET2) when the
signal at CS pin is maximum and shortest (TAFSET1) when the CS signal is minimmum. This approach reduces
the synchronous-rectifier MOSFET body-diode conduction time over a wide load-current range, thus improving
efficiency and reducing diode recovery time. The resistor divider RAEFHI and RAEF, determines the setting of the
proportional ratio between the longest and shortest delay. If CS and ADELEF are shorted, the ratio is maximized.
Connecting ADELEF to GND fixes the delay, defined only by resistor REF from DELEF to GND.
Equation 6 defines delay time tAFSET. The same Figure 1 defines the delay time tBESET.
ææ
ö
ö
5 ´ REF
TAFSET = ç ç
ns + 4ns ÷
÷
ç
÷
è è 2.65 V - CS ´ K EF ´ 1.32 ø
ø
(6)
In this equation REF is in kΩ, CS, which is the voltage at pin CS, is in volts and KEF is a numerical gain factor of
CS voltage from 0 to 1. Delay time tAFSET is in ns. This equation is an empirical approximation of measured data,
thus, there is no unit agreement in it. As an example calculation, assume REF = 15 kΩ, CS = 1 V and KEF = 0.5.
Then tAFSET is 41.7 ns. The definition of KEF is:
K EF =
R AEF
R AEF + R AEF(hi)
(7)
RAEF and RAEFHI define the portion of the voltage at pin CS applied to pin ADELEF (See the Typical Application
Diagram ). KEF defines how significantly the delay time depends on the CS voltage. KEF varies from 0, with the
ADELEF pin shorted to ground (RAEF = 0) and the delay independent of the CS voltage, to 1, with ADELEF tied
to CS (RAEFHI = 0).
NOTE
The allowed resistor range on DELEF, REF is 13 kΩ to 90 kΩ.
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The plots in Figure 10 and Figure 11 show delay time settings as function of the CS voltage and KEF for two
different conditions: REF = 13 kΩ (Figure 10) and REF = 90 kΩ (Figure 11)
TIME DELAY (TEF = REF = 13 kW)
vs
CS VOLTAGE
350
TAFSET, TBESET - Time Delay - ns
300
250
KA = 0.00
KA = 0.25
200
KA = 0.50
KA = 0.75
150
KA = 0.90
KA = 1.00
100
50
5
0.0
0.2
0.4
0.6
0.8
1.0
1.2
1.4
1.6
1.8
CS Voltage - V
Figure 10. Delay Time tAFSET and tBESET
(Over CS Voltage and Selected KEF for REF Equal 13 kΩ)
TIME DELAY (TAF = RBE = 90 kW)
vs
CS VOLTAGE
2000
TAFSET, TBESET - Time Delay - ns
1800
1600
1400
KA = 0.0
1200
KA = 0.4
1000
KA = 0.8
KA = 0.5
KA = 0.9
800
KA = 1.0
600
400
200
5
0.0
0.2
0.4
0.6
0.8
1.0
1.2
1.4
1.6
1.8
CS Voltage - V
Figure 11. Delay Time tAFSET and tBESET
(Over CS Voltage and Selected KEF for REF Equal 90 kΩ)
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Minimum Pulse (TMIN)
Resistor RTMIN from the TMIN pin to GND sets the fixed minimum pulse, TMIN, applied to the output rectifier,
enabling ZVS of the primary switches at light load. If the output PWM pulse demanded by the feedback loop is
shorter than TMIN, then the controller proceeds to the burst mode of operation, where the off-time dictated by the
feedback loop follows an even number of TMIN pulses. The time it takes to raise the sufficient magnetizing
current in the power transformer to maintain ZVS dictates the proper selection of TMIN. Equation 8 defines the
minimum pulse TMIN.
TMIN = (5.92 ´ RTMIN ) ns
(8)
In this equation, RTMIN is in kΩ and TMIN is in ns.
NOTE
The minimum allowed resistor on TMIN, RTMIN is 13 kΩ.
The related plot is Figure 12.
MINIMUM TIME
vs
RESISTOR SETTING
900
800
TMIN - Minimum Time - ns
700
600
500
400
300
200
100
0
5
15 25 35 45 55 65 75 85 95 105 115 125
RTMIN - Resistor Setting - kW
Figure 12. Minimum Time TMIN Over Setting Resistor RTMIN
Equation 9 determines the value of minimum duty cycle DMIN.
(
)
DMIN = TMIN ´ FSW (osc ) ´ 10-4 %
(9)
Here, fSW(osc) is oscillator frequency in kHz, TMIN is the minimum pulse in ns, and DMIN is in percent.
Burst Mode
If the converter is commanding a duty cycle lower than TMIN, then the controller goes into burst mode. The
controller always delivers an even number of power cycles to the power transformer. The controller always stops
its bursts with the OUTB and OUTC power-delivery cycle. If the controller still demands a duty cycle less than
TMIN, then the controller goes into shutdown mode. Then it waits until the converter demands a duty cycle equal
or higher than TMIN before the controller puts out TMIN or a PWM duty cycle as dictated by the COMP voltage
pin.
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Switching Frequency Setting (RT)
Connecting an external resistor RT between the RT and VREF pins sets the fixed-frequency operation and
configures the controller as a master providing synchronization output pulses at the SYNC pin with 0.5 duty cycle
and frequency equal to the internal oscillator. To set the converter in slave mode, connect the external resistor
RT between the RT pin and GND, and place an 825-kΩ resistor from the SS pin to GND in parallel to the SS_EN
capacitor. This configures the controller as a slave. The slave controller operates with 90° phase shift relatively to
the master converter if their SYNC pins are tied together. The switching frequency of the converter is equal to the
frequency of output pulses. The following Equation 10 defines the nominal switching frequency of the converter
configured as a master (resistor RT between the RT pin and VREF). On the UCC28950-Q1 there is an internal
clock oscillator frequency which is twice that of the controller output frequency.
FSW (nom)
æ
ö
ç
÷
3
2.5 ´ 10
ç
÷ kHz
=
çæ
RT
kW ö ÷
+ 1´
çç ç
÷÷
V ø ø÷
è è VREF - 2.5 V
(10)
In this equation, RT is in kΩ, VREF is in volts, and fSW(nom) is in kHz. This is also an empirical approximation, and
thus there is no unit agreement. Assume, for example, VREF = 5 V, RT = 65 kΩ. Then the switching frequency
fSW(nom) is 92.6 kHz.
Equation 11 defines the nominal switching frequency of the converter with the converter configured as a slave
and resistor RT connected between the RT pin and GND.
FSW (nom)
æ
ö
ç
÷
3
2.5 ´ 10
ç
÷ kHz
=
ç æ RT
kW ö ÷
+ 1´
çç
÷
V ÷ø ø
è è 2.5 V
(11)
In this equation, RT is in kΩ and f is in kHz. Notice that for VREF = 5 V, Equation 10 and Equation 11 yield the
same results.
The plot in Figure 13 shows how fSW(nom) depends on the resistor RT value when the VREF = 5 V. As it is seen
from Equation 10 and Equation 11, the switching frequency fSW(nom) setting is for the same value for either master
or slave configuration, provided the same resistor value RT is used.
SWITCHING FREQUENCY
vs
RESISTOR RT VALUE
1000
FSW(nom) - Switching Frequency - kHz
900
800
700
600
500
400
300
200
100
0
5
15 25 35 45 55 65 75 85 95 105 115 125
RT - Resistor - kW
Figure 13. Converter Switching Frequency fSW(nom) Over Resistor RT Value
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Slope Compensation (RSUM)
Slope compensation is the technique that adds additional ramp signal to the CS signal and applies to the:
• Input of PWM comparator in case of peak current mode control
• Input of cycle-by-cycle current limit comparator
This prevents sub-harmonic oscillation at D > 50% (some publications suggest it might happen even at D <
50%). At low duty cycle and light load, the slope-compensation ramp reduces the noise sensitivity of peakcurrent-mode control.
Too much additional slope-compensation ramp reduces benefits of PCM control. In the case of cycle-by-cycle
current limit, the average current limit becomes lower, and this might reduce the start-up capability with large
output capacitance. The optimal compensation slope varies depending on duty cycle, LO and LM.
The controller operating in peak-current-mode control or during the cycle-by-cycle current limit at duty cycle
above 50% requires slope compensation. Placing a resistor from the RSUM pin to ground allows the controller to
operate in peak-current-control mode. Connecting the RSUM pin through a resistor to VREF switches the
controller to voltage-mode control with the internal PWM ramp. However, the resistor value still provides CS
signal compensation for cycle-by-cycle current limit. In other words, in VMC, slope compensation is applied only
to the cycle-by-cycle comparator. While in PCM, the slope compensation applies to both the PWM and cycle-bycycle current-limit comparators.
Figure 14 shows the operational logic of the slope-compensation circuit.
COMP
4
+
+
Oscillator
VREF
VCM
0.85 V
CLK
PCM
Ramp
Generator
VMC
RAMP
Cycle-by-Cycle ILIM
RSUM
11
Two Direction
Current Sense
Ramp
Summing
CS_SLOPECOMP
+
CS 15
2V
+
-
Mode Select
GND
PCM
7
GND
Figure 14. Operational Logic of Slope-Compensation Circuit
Equation 12 defines the slope of the additional ramp, me, added to CS signal by placing a resistor from the
RSUM pin to ground.
æ
öV
2.5
me = ç
÷
è 0.5 ´ RSUM ø ms
22
(12)
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If the resistor from the RSUM pin connects to the VREF pin, then the controller operates in voltage mode control,
still having the slope compensation added to CS signal used for the cycle-by-cycle current limit. In such a case,
Equation 13 defines the slope.
æ (V - 2.5 V) ö V
me = ç REF
÷
è 0.5 ´ RSUM ø ms
(13)
In Equation 12 and Equation 13, the VREF is in volts, RSUM is in kΩ, and me is in V/µs. These are empirical
equations without unit agreement. As an example, substituting VREF = 5 V and RSUM = 40 kΩ yields the result
0.125 V/µs. Figure 15 shows the related plot of me as function of RSUM. Because VREF = 5 V, the plots
generated from Equation 12 and Equation 13 coincide.
SLOPE
vs
RESISTOR
0.50
0.45
0.40
Slope - V/ms
0.35
0.30
0.25
0.20
0.15
0.10
0.05
0
5
20
40
60
80
100 120 140 160 180 200
Rsum - Resistor - kW
Figure 15. Slope of the Added Ramp Over Resistor RSUM
NOTE
The recommended resistor range for RSUM is 10 kΩ to 1 MΩ.
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Dynamic SR ON/OFF Control (DCM Mode)
The voltage at the DCM pin provided by the resistor divider Rdcmhi between the VREF pin and DCM, and Rdcm
from the DCM pin to GND, sets the percentage of the 2-V current-limit threshold for the current-sense pin, (CS).
If the CS pin voltage falls below the DCM pin threshold voltage, then the controller initiates the light-load powersaving mode, and shuts down the synchronous rectifiers, OUTE and OUTF. If the CS pin voltage is higher than
the DCM pin threshold voltage, then the controller runs in CCM mode. Connecting the DCM pin to VREF makes
the controller run in DCM mode and shuts off both outputs OUTE and OUTF. Shorting the DCM pin to GND
disables the DCM feature, and the controller runs in CCM mode under all conditions.
VREF
1
20 mA
RDCM(hi)
CS
DCM
R = 77 kW
PWM
DCM_COMP
15
2-Cycle
Counter
+
R = 77 kW
0 = DCM
1 = CCM
12
C = 6.5 pF
RDCM
C = 6.5 pF
Other Blocks
Figure 16. DCM Functional Block
DUTY CYCLE
vs
LOAD CURRENT
Moving into
DCM Mode
0.8
VS(max)
Duty Cycle - %
0.6
Setting DMIN
15.6%
VS(min)
0.4
0.2
Burst Mode
Area
0
0
1
2
3
4
5
6
7
8
9
10
Load Current - A
Figure 17. Duty-Cycle Change Over Load-Current Change
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There is a nominal 20-µA switched current source used to create hysteresis. The current source is active only
when the system is in DCM Mode. Otherwise, the curent source is inactive and does not affect the node voltage.
Therefore, when in the DCM region, the DCM threshold is the voltage divider plus ΔV as explained in
Equation 14. When in the CCM region, the threshold is the voltage set by the resistor divider. When the CS pin
reaches the threshold set on the DCM pin, the system waits to see two consecutive falling-edge PWM cycles
before switching from CCM to DCM and from DCM to CCM. The magnitude of the hysteresis is a function of the
external resistor-divider impedance. Calculate the hysteresis using Equation 14:
DV = 2 ´ 10 -5
RDCMHI ´ RDCM
RDCMHI + RDCM
(14)
PWM
DCM Threshold
+ Hysteresis
CS
E
F
Figure 18. Moving From DCM to CCM Mode
PWM
DCM Threshold
+ Hysteresis
CS
E
F
Figure 19. Moving From CCM to DCM Mode
Use DCM in order to prevent reverse current in the output inductor, which could cause the synchronous FETs to
fail.
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Current Sensing (CS)
Use of the signal from the current-sense pin is for cycle-by-cycle current limit, peak-current mode control, lightload efficiency management and setting the delay time for outputs OUTA, OUTB, OUTC, OUTD and delay time
for outputs OUTE, OUTF. Connect the current-sense resistor RCS between CS and GND. Depending on layout,
to prevent a potential electrical noise interference, TI recommends putting a small R-C filter between the RCS
resistor and CS pin.
Cycle-by-Cycle Current-Limit Current Protection and Hiccup Mode
The cycle-by-cycle current limit provides peak current limiting on the primary side of the converter when the load
current exceeds its predetermined threshold. For peak-current-mode control, prevention of the controller from
false tripping due to switching noise requires a certain leading-edge blanking time. In order to save the external
RC filter for the blanking time, the device has an internal 30-ns filter at the CS input. The total propagation delay,
tCS, from the CS pin to the outputs is 100 ns. circuit still requires an external RC filter if the power stage requires
more blanking time. The 2-V, ±3% cycle-by-cycle current-limit threshold is optimal for efficient currenttransformer-based sensing. The duration of converter operation in cycle-by-cycle current limiting depends on the
value of soft-start capacitor and how severe the overcurrent condition is. Efficient sensing is achieved by the
internal discharge current IDS Equation 15 and Equation 16 at SS pin.
IDS(master ) = (-25 ´ (1 - D ) + 5 )mA
(15)
IDS(slave) = (-25 ´ (1 - D ))mA
(16)
The soft-start capacitor value also determines the so-called hiccup mode off-time duration. Figure 20 shows the
behavior of the converter during different modes of operation, along with related soft-start capacitor charge and
discharge currents.
SS Pin (V)
SS Clamp Voltage
4.65
Pull Up Threshold
3.70
3.60
Soft Start
Cycle-by-Cycle ILIM
Normal
.
Operation
OFF Time Before Restart
25 mA
Soft Restart
Fast Pull Up
by 1 kW Switch IDS = (-25 x (1-D)+5) mA
Output Enable
Threshold
ISS=25 mA
0.55
0.00
IHCC = 2.5 mA
Output Pulses (D)
Figure 20. Timing Diagram of Soft-Start Voltage VSS
26
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The largest discharge current of 20 µA is when the duty cycle is close to zero. This current sets the shortest
operation time during the cycle-by-cycle current limit, defined as:
TCL(on _ master ) =
TCL(on _ slave) =
CSS ´ (4.65 V - 3.7 V )
20 mA
(17)
CSS ´ (4.65 V - 3.7 V )
25 mA
(18)
Thus, if soft-start capacitor CSS = 100 nF is selected, then the tCL(on) time is 5 ms.
To calculate the hiccup off-time tCL(off) before the restart, use Equation 19 or Equation 20 :
TCL(off _ master ) =
TCL(off _ slave) =
C SS ´ (3.6 V - 0.55 V )
2.5 mA
(19)
CSS ´ (3.6 V - 0.55 V )
4.9 mA
(20)
With the same soft-start capacitor value of 100 nF, the off-time before the restart is 122 ms. Notice that if the
overcurrent condition happens before the soft-start capacitor voltage reaches the 3.7-V threshold during start-up,
the controller limits the current, but the soft-start capacitor continues to be charged. Immediately on reaching the
3.7-V threshold, an internal 1-kΩ rDS(on) switch quicly pulls the soft-start voltage up to the 4.65-V threshold, and
the cycle-by-cycle current-limit-duration timing starts by discharging the soft-start capacitor. Depending on
specific design requirements, the user can override default parameters by applying external charge or discharge
currents to the soft-start capacitor. Figure 20 shows the whole cycle-by-cycle current-limit and hiccup operation.
In this example, the cycle-by-cycle current limit lasts about 5 ms followed by 122 ms of off-time.
Similar to the overcurrent condition, the user can override the hiccup mode with restart by connecting a pullup
resistor between the SS and VREF pins. If the pullup current provided by the resistor exceeds 2.5 µA, then the
controller remains in the latch-off mode. In this case, calculate the value of an external soft-start capacitor with
the additional pullup current taken into account. One can reset the latch-off mode externally by forcibly
discharging the soft-start capacitor below 0.55 V or lowering the VDD voltage below the UVLO threshold.
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Synchronization (SYNC)
The UCC28950-Q1 allows flexible configuration of converters operating in synchronized mode by connecting all
SYNC pins together and by configuration of the controllers as master and/or slaves. The controller configured as
master (resistor between RT and VREF) provides synchronization pulses at the SYNC pin with the frequency
equal to 2× the converter frequency fSW(nom) and 0.5 duty cycle. The controller configured as a slave (resistor
between RT and GND and an 825-kΩ resistor from the SS_EN pin to GND) does not generate the
synchronization pulses. The slave controller synchronizes its own clock to the falling edge of the synchronization
signal, thus operating 90° phase-shifted versus the master converter frequency fSW(nom). Because the slave is
synchronized to the falling edge of the SYNC pulses, the slave operates at 180˚ delayed versus the CLK of the
master CLK or 90˚ delayed versus output-switching pulses of the master.
Such operation between master and slave provides the maximum input-capacitor and output-capacitor ripplecancellation effect by tying the inputs and outputs of the converters together. To avoid system issues during the
synchronized operation of a few converters, take care of the following conditions.
• For any slave-configured converter, the SYNC frequency must be greater than or equal to 1.8 times the
converter frequency.
• A slave converter does not start until it has received at least one synchronization pulse.
• For any converters are configured as slaves, then each converter operates at its own frequency without
synchronization after receiving at least one synchronization pulse. Thus, If there is an interruption of
synchronization pulses at the slave converter, then the controller uses its own internal clock pulses to
maintain operation based on the RT value connected to GND in the slave converter.
• In master mode, SYNC pulses start after the SS pin passes its enable threshold, which is 0.55 V.
• A slave starts generating SS/EN voltage even without having received synchronization pulses.
• RI recommends that the SS on the master controller start before the SS on the slave controller; therefore, for
proper operation, the SS/EN pin on the master converter must reach its enable threshold voltage before
SS/EN on the slave converter starts. On the same note, TI recommends that the tMIN resistors on both master
and slave be set at the same value.
CLK
SYNC_OUT
A
B
Figure 21. SYNC_OUT (Master Mode) Timing Diagram
SYNC_IN
CLK
A
B
Figure 22. SYNC_IN (Slave Mode) Timing Diagram
28
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Outputs (OUTA, OUTB, OUTC, OUTD, OUTE, OUTF)
•
•
•
•
•
•
All MOSFET control outputs have 0.2-A drive capability.
The control outputs are configured as P-MOS and N-MOS totem poles with typical rDS(on) of 20 Ω and 10 Ω,
respectively.
The control outputs are capable of charging 100-pF capacitor within 12 ns and discharging within 8 ns.
The amplitude of the output control pulses is equal to VDD.
Design of the control outputs is for use with external-gate MOSFET/IGBT drivers.
Design optimization prevents the latch-up of outputs, which extensive tests have verified.
The UCC28950-Q1 has outputs OUTA and OUTB driving the active leg, initiating the duty-cycle leg of the power
MOSFETs in the phase-shifted full-bridge power stage, and outputs OUTC and OUTD driving the passive leg,
completing the duty cycle leg, as the typical timing diagram in Figure 50 shows. Optimization of outputs OUTE
and OUTF is for driving the synchronous rectifier MOSFETs (Figure 23). These outputs, designed to drive
relatively small capacitive loads like inputs of external MOSFET or IGBT drivers, have 200-mA peak-current
capabilities. Recommended load capacitance should not exceed 100 pF. The amplitude of output signal is equal
to the VDD voltage.
The capacitors COSS shown in Figure 23 are internal MOSFET capacitances that must be taken into account
during the design procedure to estimate the zero-voltage condition and switching losses.
+
Lm
COSS
OUTA
VS
COSS
OUTC
LLK
RPR
XT
A
B
COSS
COSS
OUTB
OUTD
-
COSS
COSS
OUTE
OUTF
LO
DCR
CO
VOUT
-
+
Figure 23. Power Stage
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Supply Voltage (VDD)
Connect this pin to a bias supply in the 8-V to 17-V range. Place high quality, low-ESR and -ESL, ceramic
bypass capacitor CVDD of at least 1-µF, from this pin to GND. TI recommends using a 10-Ω resistor in series with
the VDD pin to form an RC filter with the CVDD capacitor.
Ground (GND)
This node is the reference for all other signals. TI recommends having a separate, quiet analog plane connected
in one place to the power plane. The analog plane combines the components related to the pins VREF, EA+,
EA-, COMP, SS/EN, DELAB, DELCD, DELEF, TMIN, RT, RSUM. The power plane combines the components
related to the pins DCM, ADELEF, ADEL, CS, SYNC, OUTF, OUTE, OUTD, OUTC, OUTB, OUTA, and VDD.
Figure 24 shows an example of layout and ground-plane connections.
R1
VREF
GND 24
2
EA+
VDD 23
3
EA-
OUTA 22
A
4
COMP
OUTB 21
B
CSS
5
SS/EN
OUTC 20
C
RAB
6
DELAB
OUTD 19
D
RCD
7
DELCD
OUTE 18
E
REF
8
DELEF
OUTF 17
F
RT(min)
9
TMIN
SYNC 16
SYNC
C1
VDD
R5
R4
R6
CVDD
1
R3
VSENSE
UCC28950
CREF
R2
C3
C2
ENABLE
Analog
Plane
10 RT
RT
Power
Plane
CS 15
RA(hi)
RSUM)
11 RSUM
ADEL 14
RA
RDCM(hi)
VREF
12 DCM
ADELEF 13
RAEF(hi)
Current Sense
R7
RCS
RDCM
RAEF
Figure 24. Layout Recommendation for Analog and Power Planes
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TYPICAL CHARACTERISTICS
UVLO THRESHOLDS
vs
TEMPERATURE
UVLO HYSTERESIS
vs
TEMPERATURE
640
UVLO - Under Voltage Lockout Hysteresis - mV
UVLO - Under Voltage Lockout Thresholds - V
7.6
UVLO_RTH
7.4
7.2
7.0
UVLO_FTH
6.8
6.6
6.4
630
620
UVLO_HYST
610
600
590
580
6.2
-40
25
125
-40
TJ - Temperature - °C
Figure 25.
125
Figure 26.
SUPPLY CURRENT
vs
TEMPERATURE
STARTUP CURRENT
vs
TEMPERATURE
250
3.9
3.8
IDD - Startup Current - mA
IDD - Operating Supply Current - mA
25
TJ - Temperature - °C
3.7
3.6
200
150
100
3.5
3.4
50
-40
25
125
-40
TJ - Temperature - °C
25
125
TJ - Temperature - °C
Figure 27.
Figure 28.
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TYPICAL CHARACTERISTICS (continued)
VOLTAGE REFERENCE (VDD = 12 V)
vs
TEMPERATURE
LINE VOLTAGE REGULATION (ILOAD = 10 mA)
vs
TEMPERATURE
5.010
5.001
ILOAD = 10 mA
5.000
ILOAD = 1 mA
4.995
ILOAD = 10 mA
4.990
4.985
VREF _ 10 mA _ 12 VDD
4.999
VREF - Line Voltage Regulation - V
VREF - Voltage Reference - V
5.005
ILOAD = 20 mA
4.980
4.997
VREF _ 10 mA _ 10 VDD
4.995
4.993
4.991
VREF _ 10 mA _ 8 VDD
4.989
4.975
4.987
-40
25
125
4.985 -40
TJ - Temperature - °C
125
TJ - Temperature - °C
Figure 29.
Figure 30.
SHORT CIRCUIT CURRENT
vs
TEMPERATURE
MAXIMUM DUTY CYCLE
vs
TEMPERATURE
38.5
95.4
95.2
DMAX - Maximum Duty Cycle - %
38.0
Short Circuit Current - mA
25
37.5
37.0
36.5
36.0
95.0
94.8
94.6
94.4
94.2
94.0
35.5
93.8
35.0
93.6
-40
25
125
-40
TJ - Temperature - °C
Figure 31.
32
25
125
TJ - Temperature - °C
Figure 32.
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TYPICAL CHARACTERISTICS (continued)
MAXIMUM SWITCHING FREQUENCY
vs
TEMPERATURE
NOMINAL SWITCHING FREQUENCY
vs
TEMPERATURE
1079
FSW(max) - Maximum Switching Frequency - Hz
FSW(nom) - Nominal Switching Frequency - Hz
95.4
95.0
94.6
94.0
1059
1039
1019
999
93.6
-40
-40
125
25
25
125
TJ - Temperature - °C
TJ - Temperature - °C
Figure 33.
Figure 34.
ERROR AMPLIFIER OFFSET VOLTAGE
vs
TEMPERATURE
0.00
VOLTAGE ERROR AMPLIFIER
(Open Loop Gain)
vs
TEMPERATURE
125
120
-0.10
AVOL - Voltage Error Amplifier - dB
Error Amplifier OFFSET voltage - mV
-0.05
-0.15
-0.20
VIO = 500 mV
-0.25
VIO = 3.6 V
-0.30
-0.35
VIO = 2.5 V
-0.40
115
110
105
100
95
90
-0.45
-0.50
85
-40
25
125
-40
TJ - Temperature - °C
25
125
TJ - Temperature - °C
Figure 35.
Figure 36.
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TYPICAL CHARACTERISTICS (continued)
ISS CHARGE CURRENT
vs
TEMPERATURE
SHUTDOWN/RESTART/RESET THRESHOLD
vs
TEMPERATURE
26.0
VSS(std) - Shutdown/Restart/Reset Threshold - V
0.60
ISS - Charge Current - mA
25.5
25.0
24.5
24.0
23.5
0.55
0.50
0.45
0.40
0.35
0.30
-40
125
25
-40
TJ - Temperature - °C
25
125
TJ - Temperature - °C
Figure 37.
Figure 38.
SS PULL-UP THRESHOLD
vs
TEMPERATURE
SS CLAMP VOLTAGE
vs
TEMPERATURE
4.69
3.71
VSS(CL) - SS Clamp Voltage - V
VSS(pu) - SS Pullup Threshold - V
4.69
3.71
3.70
3.70
4.68
4.68
4.68
4.68
4.68
4.67
4.67
3.69
4.67
-40
125
25
-40
TJ - Temperature - °C
Figure 39.
34
25
125
TJ - Temperature - °C
Figure 40.
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TYPICAL CHARACTERISTICS (continued)
CURRENT SENSE CYCLE-BY-CYCLE LIMIT
vs
TEMPERATURE
CURRENT SENSE PROPAGATION DELAY
vs
TEMPERATURE
110
TCS(prop) - Current Sense Propagation Delay - ns
VCS(lim) - Current Sense Cycle-By-Cycle Limit - V
1.996
1.994
1.992
1.990
1.988
1.986
1.984
107
104
101
98
95
-40
125
25
-40
TJ - Temperature - °C
125
TJ - Temperature - °C
Figure 41.
Figure 42.
OUTPUTS SINK RESISTANCE
vs
TEMPERATURE
OUTPUTS SINK RESISTANCE
vs
TEMPERATURE
17.5
RSINK - Outputs Sink Resistance - W
17.5
RSINK - Outputs Sink Resistance - W
25
RSINK_OUTF
RSINK_OUTD
15.5
RSINK_OUTA
13.5
11.5
9.5
RSINK_OUTE
RSINK_OUTC
15.5
RSINK_OUTB
13.5
11.5
9.5
7.5
7.5
-40
25
125
-40
25
125
TJ - Temperature - °C
TJ - Temperature - °C
Figure 43.
Figure 44.
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TYPICAL CHARACTERISTICS (continued)
OUTPUTS SOURCE RESISTANCE
vs
TEMPERATURE
OUTPUTS SOURCE RESISTANCE
vs
TEMPERATURE
25
RSRC - Outputs Source Resistance - W
RSRC - Outputs Source Resistance - W
25
RSRC_OUTF
RSRC_OUTC
23
RSRC_OUTA
21
19
17
15
RSRC_OUTE
RSRC_OUTD
23
RSRC_OUTB
21
19
17
15
-40
25
125
-40
25
TJ - Temperature - °C
125
TJ - Temperature - °C
Figure 45.
Figure 46.
DEAD TIME DELAY
vs
TEMPERATURE
DEAD TIME DELAY
vs
TEMPERATURE
50
280
TCDSET2
270
TOFFTIME - Dead Time Delay - ns
TOFFTIME - Dead Time Delay - ns
TCDSET1
TABSET1
45
40
TAFSET1
35
TABSET2
260
250
TAFSET2
240
TBESET2
230
TBESET1
30
220
-40
25
125
-40
TJ - Temperature - °C
Figure 47.
36
25
125
TJ - Temperature - °C
Figure 48.
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TYPICAL CHARACTERISTICS (continued)
DCM THRESHOLD
vs
TEMPERATURE
0.405
DCM - DCM Threshold - V
0.400
0.395
0.390
0.385
0.380
0.380
0.375
-40
25
125
TJ - Temperature - °C
Figure 49.
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APPLICATION INFORMATION
UCC28950-Q1 Application Description
Using the synchronous rectification technique, a control algorithm providing ZVS conditions over the entire load
current range, accurate adaptive timing of the control signals between primary and secondary FETs, and special
operating modes at light load for the highest efficiency and power saving achieves the efficiency improvement of
a phase-shifted full-bridge dc-dc converter with the UCC28950-Q1. Figure 50 shows a simplified electrical
diagram of this converter. The location of the controller device is on the secondary side of converter, although it
could be on primary side as well. Location on the secondary side allows easy power-system level communication
and better handling of some transient conditions that require fast, direct control of the synchronous rectifier
MOSFETs. The power stage includes primary-side MOSFETs, QA, QB, QC, QD and secondary-side
synchronous rectifier MOSFETs, QE and QF. For example, for the 12-V output converters in power supplies for
servers use of the center-tapped rectifier scheme with an L-C output filter as a popular choice.
To maintain high efficiency at different output power conditions, the converter operates in nominal synchronous
rectification mode at mid- and high-output power levels, transitioning to the diode-rectifier mode at light load, and
further followed by the burst mode as the output power becomes even lower. All these transitions are based on
current sensing on the primary side, using the current-sense transformer in this specific case.
TSW(nom)
TABSET2
OUTA
TABSET1
TCDSET2
OUTB
OUTC
TSW(osc)
TCDSET1
OUTD
TBESET1
OUTE
TAFSET1
TBESET2
OUTF
TAFSET2
IPR
VDSQE
TON = 0.5 x D x TSW(nom)
VDSQF
VOUT x (1-D) / D
VLOUT
VOUT
ILOUT
IOUT
Figure 50. Major Waveforms of Phase-Shifted Converter
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Figure 50 shows major waveforms of the phase-shifted converter during the nominal operation mode. The upper
six waveforms in Figure 50 show the output drive signals of the controller. In the nominal mode, the outputs
OUTE and OUTF overlap during the part of the switching cycle when the circuitry causes both rectifier MOSFETs
to conduct and shorts the windings of the power transformer. Current, IPR, is the current flowing through the
primary winding of power transformer. The bottom four waveforms show the drain-source voltages of the rectifier
MOSFETs, VDS_QE and VDS_QF, the voltage at the output inductor, V LOUT, and the current through the output
inductor, I LOUT. Proper timing between the primary switches and synchronous rectifier MOSFETs is critical to
achieve highest efficiency and reliable operation in this mode. The controller device adjusts the turnoff timing of
the rectifier MOSFETs as a function of load current to ensure the minimum conduction time and reverse-recovery
losses of their internal body diodes.
ZVS is an important feature of relatively high-input-voltage converters to reduce switching losses associated with
the internal parasitic capacitances of power switches and transformers. The controller ensures ZVS conditions
over the entire load-current range by adjusting the delay time between the primary MOSFETs switching in the
same leg in accordance with the load variation. The controller also limits the minimum on-time pulse applied to
the power transformer at light load, allowing the storage of sufficient energy in the inductive components of the
power stage for the ZVS transition.
While the load current coninues reducing from the mid-load current down to the no-load condition, the controller
selects the most-efficient power-saving mode by moving the converter from the nominal operation mode to the
discontinuous-current diode-rectification mode and, eventually, at very light-load and at no-load condition, to the
burst mode. Figure 51 shows these modes and the related output signals, OUTE, OUTF, driving the rectifier
MOSFETs.
OUTE
(CCM Mode)
OUTF
(CCM Mode)
OUTE
OUTE and OUTF are disabled if VCS < VDCM
OUTF
OUTE and OUTF are disabled if VCS < VDCM
Burst Mode at light load with TMIN maintaining ZVS
(The time scale is different versus above diagram)
Transformer
Winding
Magnetizing
Current
Figure 51. Major Waveforms During Transitions Between Different Operating Modes
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It is necessary to prevent the reverse current flow through the synchronous rectifier MOSFETs and output
inductor at light load, during parallel operation, and during some transient conditions. Such reverse current
results in circulating of some extra energy between the input-voltage source and the load and, therefore, causes
increased losses and reduces efficiency. Another negative effect of such reverse current is the loss of the ZVS
condition. The suggested control algorithm prevents reverse current flow, still maintaining most of the benefits of
synchronous rectification by switching off the drive signals of the rectifier MOSFETs in a predetermined way. At
some predetermined load-current threshold, the controller disables outputs OUTE and OUTF by bringing them
down to zero.
Synchronous rectification using MOSFETs requires some electrical energy to drive the MOSFETs. There is a
condition below some light-load threshold when the MOSFET drive related losses exceed the saving provided by
synchronous rectification. At such light loads, it is best to disable the drive circuit and use the internal body
diodes of the rectifier MOSFETs, or external diodes in parallel with the MOSFETs, for more-efficient rectification.
In most practical cases, disabling the drive circuit close to DCM mode is necessary. This mode of operation is
discontinuous-current diode-rectification mode.
At very light-load and no-load conditions, the duty cycle, demanded by the closed-feedback-loop control circuit
for output voltage regulation, can be very low. This could lead to loss of the ZVS condition and increased
switching losses. To avoid the loss of ZVS, the control circuit limits the minimum on-time pulse applied to the
power transformer, using the resistor from the TMIN pin to GND. Therefore, the only way to maintain regulation
at very light load and in the no-load condition is to skip some pulses. The controller skips pulses in a controllable
manner to avoid saturation of the power transformer. This is operation in burst mode. In burst mode, there is
always an even number of pulses applied to the power transformer before the skipping off-time. Thus, the flux in
the core of the power transformer always starts from the same point during the start of every burst of pulses.
Voltage Loop Compensation Recommendation
For best results in the voltage loop TI recommends using a Type 2 or Type 3 compensation network (Figure 52).
A Type 2 compensation network does not require passive components CZ2 and RZ2. Type 1 compensation is not
versatile enough for a phase-shifted full bridge. When evaluating COMP for best results, TI recommends putting
a 1-kΩ resistor between the scope probe and the COMP pin of the UCC28950-Q1.
VOUT
CZ2
VREF
EA+
RI
+
EA1 kW
RD
RZ2
CZ1
R
RZ1
CP1
R
When evaluating COMP, for best
results put a 1-kW resistor between
COMP and probe.
Figure 52. Type 3 Compensation Evaluation
40
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Product Folder Link(s): UCC28950-Q1
UCC28950-Q1
www.ti.com
SLUSAG4A – APRIL 2011 – REVISED JULY 2012
Experimental Results Example
The following experimental results are based on 660-W output-power prototype of a phase-shifted full-bridge dcdc converter. The input voltage is 300 V to 400 V and the output is 12 V, 55 A. The primary MOSFETs are
SPA11N60CFD and the synchronous rectifier MOSFETs are FDP047AN08A0, two in parallel. Figure 53 shows
the measured efficiency of the prototype.
EFFICIENCY
vs
LOAD CURRENT
100
VIN = 300 V with LRES
98
96
Efficiency - %
94
92
VIN = 350 V with LRES
90
88
86
84
82
VIN = 400 V with LRES
80
0
5
10
15
20
25
30
35
40
45
50
55
Load Current - A
Figure 53. Efficiency of the Prototype Phase-Shifted Converter
(VIN = 300 V, 350 V and 400 V, VOUT = 12 V)
Because of the power saving need even at very light and no-load conditions, the user must carefully optimize
operation at light-load conditions to set the proper boundaries between different operation modes. Figure 54
shows the result of this optimization. This plot demonstrates the power savings while moving from the
synchronous rectification mode above 1-A load current, into the discontinuous current mode with the diode
rectification between 0.3-A and 1-A load current, and eventually into the burst mode operation at load current
below 0.3 A.
LIGHT-LOAD POWER LOSSES
vs
LOAD CURRENT
12
11
Light-Load Power Losses - W
10
DCM Mode
with Diode
Rectification
9
8
7
CCM Mode with
Synchronous FETs
6
5
4
3
Burst Mode
2
1
0
0
0.2
0.4
0.6
0.8 1.0
1.2
1.4
1.6
1.8 2.0
Load Current - A
Figure 54. Power Losses of the Prototype at Light-Load and No-Load Conditions
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Product Folder Link(s): UCC28950-Q1
41
UCC28950-Q1
SLUSAG4A – APRIL 2011 – REVISED JULY 2012
www.ti.com
REVISION HISTORY
Changes from Original (April, 2011) to Revision A
Page
•
Changed synchronous rectifiers switching delays to switching delays of the synchronous rectifiers .................................. 1
•
Changed UCC28950 Typical Application Diagram ............................................................................................................... 2
•
Changed 105°C to 125°C ..................................................................................................................................................... 3
•
Removed junction-to-case (bottom) thermal resistance row ................................................................................................ 3
•
Changed TA max value from 105 to 125 and removed operating junction temperature row. .............................................. 4
•
Changed Functional Block Diagram ..................................................................................................................................... 9
•
Changed Typical Application Diagram ................................................................................................................................ 10
•
Added cross-reference for block diagram ........................................................................................................................... 14
•
Changed defined as VNI by 0.55 V to V(SS/EN) ≥ VNI / 0.55 V in the soft start and enable section. .............................. 14
•
Removed the word always and a comma so the last sentece reads: Usually outputs C and D have ZVS if sufficient
delay is provided. ................................................................................................................................................................ 16
•
Added Figure 8 ................................................................................................................................................................... 17
•
Changed CS and ADELEF are tied to CS and ADELEF are shorted ................................................................................ 18
•
Changed Equation .............................................................................................................................................................. 18
•
Added Typical Application Diagram .................................................................................................................................... 18
•
Changed "This" to "Efficient sensing" ................................................................................................................................. 26
42
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Copyright © 2011–2012, Texas Instruments Incorporated
Product Folder Link(s): UCC28950-Q1
PACKAGE OPTION ADDENDUM
www.ti.com
24-Jul-2012
PACKAGING INFORMATION
Orderable Device
UCC28950TPWRQ1
Status
(1)
Package Type Package
Drawing
ACTIVE
TSSOP
PW
Pins
Package Qty
24
2000
Eco Plan
(2)
Green (RoHS
& no Sb/Br)
Lead/
Ball Finish
MSL Peak Temp
(3)
Samples
(Requires Login)
CU NIPDAU Level-1-260C-UNLIM
(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)
Eco Plan - The planned eco-friendly classification: Pb-Free (RoHS), Pb-Free (RoHS Exempt), or Green (RoHS & no Sb/Br) - please check http://www.ti.com/productcontent for the latest availability
information and additional product content details.
TBD: The Pb-Free/Green conversion plan has not been defined.
Pb-Free (RoHS): TI's terms "Lead-Free" or "Pb-Free" mean semiconductor products that are compatible with the current RoHS requirements for all 6 substances, including the requirement that
lead not exceed 0.1% by weight in homogeneous materials. Where designed to be soldered at high temperatures, TI Pb-Free products are suitable for use in specified lead-free processes.
Pb-Free (RoHS Exempt): This component has a RoHS exemption for either 1) lead-based flip-chip solder bumps used between the die and package, or 2) lead-based die adhesive used between
the die and leadframe. The component is otherwise considered Pb-Free (RoHS compatible) as defined above.
Green (RoHS & no Sb/Br): TI defines "Green" to mean Pb-Free (RoHS compatible), and free of Bromine (Br) and Antimony (Sb) based flame retardants (Br or Sb do not exceed 0.1% by weight
in homogeneous material)
(3)
MSL, Peak Temp. -- The Moisture Sensitivity Level rating according to the JEDEC industry standard classifications, and peak solder temperature.
Important Information and Disclaimer:The information provided on this page represents TI's knowledge and belief as of the date that it is provided. TI bases its knowledge and belief on information
provided by third parties, and makes no representation or warranty as to the accuracy of such information. Efforts are underway to better integrate information from third parties. TI has taken and
continues to take reasonable steps to provide representative and accurate information but may not have conducted destructive testing or chemical analysis on incoming materials and chemicals.
TI and TI suppliers consider certain information to be proprietary, and thus CAS numbers and other limited information may not be available for release.
In no event shall TI's liability arising out of such information exceed the total purchase price of the TI part(s) at issue in this document sold by TI to Customer on an annual basis.
OTHER QUALIFIED VERSIONS OF UCC28950-Q1 :
• Catalog: UCC28950
NOTE: Qualified Version Definitions:
• Catalog - TI's standard catalog product
Addendum-Page 1
PACKAGE MATERIALS INFORMATION
www.ti.com
24-Jul-2012
TAPE AND REEL INFORMATION
*All dimensions are nominal
Device
UCC28950TPWRQ1
Package Package Pins
Type Drawing
TSSOP
PW
24
SPQ
Reel
Reel
A0
Diameter Width (mm)
(mm) W1 (mm)
2000
330.0
16.4
Pack Materials-Page 1
6.95
B0
(mm)
K0
(mm)
P1
(mm)
8.3
1.6
8.0
W
Pin1
(mm) Quadrant
16.0
Q1
PACKAGE MATERIALS INFORMATION
www.ti.com
24-Jul-2012
*All dimensions are nominal
Device
Package Type
Package Drawing
Pins
SPQ
Length (mm)
Width (mm)
Height (mm)
UCC28950TPWRQ1
TSSOP
PW
24
2000
367.0
367.0
38.0
Pack Materials-Page 2
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