UCC3884D [TI]
Frequency Foldback Current Mode PWM Controller;
| 型号: | UCC3884D |
| 厂家: | 
TEXAS INSTRUMENTS |
| 描述: | Frequency Foldback Current Mode PWM Controller 信息通信管理 开关 光电二极管 |
| 文件: | 总12页 (文件大小:315K) |
| 中文: | 中文翻译 | 下载: | 下载PDF数据表文档文件 |
UCC2884
UCC3884
www.ti.com............................................................................................................................................. SLUS160C–AUGUST 1999–REVISED NOVEMBER 2008
Frequency Foldback Current Mode PWM Controller
1
FEATURES
DESCRIPTION
•
Frequency Foldback Reduces Operating
Frequency Under Fault Conditions
The UCC3884 is a high performance current mode
PWM controller intended for single ended switch
mode power supplies. The chip implements
•
•
•
•
•
•
Accurate Programmable Volt-Second Clamp
Programmable Maximum Duty Cycle Clamp
Oscillator Synchronization
a
frequency foldback scheme that decreases the
oscillator frequency as the output voltage falls below
a programmed value. This technique decreases the
average output current sourced into a low impedance
load which can occur during an output short circuit or
overload condition. Excessive short circuit current is
more prevalent in high frequency converters where
the propagation delay and switch turn-off time forces
Overcurrent Protection
Shutdown With Full Soft Start
Wide Gain Bandwidth Amplifier (GBW > 2.5
MHz)
•
•
Current Mode Operation
Precision 5-V Reference
a
minimum attainable duty cycle. An accurate
volt-second clamp limits the duty cycle during line or
load transient conditions which could otherwise
saturate the transformer. The volt-second clamp may
also be used with an external overvoltage protection
circuit to handle fault conditions such as current
sense disconnect or current transformer saturation.
The frequency foldback, volt-second clamp,
cycle-by-cycle current limit, and overcurrent shutdown
provide a rich set of protection features for use in
peak current-mode pulse width modulators.
OSCILLATOR SYNCHRONIZATION
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 © 1999–2008, Texas Instruments Incorporated
UCC2884
UCC3884
SLUS160C–AUGUST 1999–REVISED NOVEMBER 2008............................................................................................................................................. www.ti.com
ABSOLUTE MAXIMUM RATINGS(1)
VALUE
UNIT
Supply voltage
15
V
Output sink current
1
A
V
Output source current
All other pins
0.5
6
Storage temperature
Junction temperature
Lead temperature (soldering, 10 sec)
–65 TO 150
–40 TO 150
300
°C
(1) Currents are positive into, negative out of the specified terminal.
ORDERING INFORMATION
PACKAGED DEVICES(1)
TJ
SOP (D)
PDIP(N)
-40°C to 85°C
0°C to 70°C
UCC2884D (16)
UCC3884D (16)
UCC2884N (16)
UCC3884N (16)
(1) Both the D and N packages are available taped and reeled (indicated by the TR suffix on the device type e.g., UCC2884DTR)
CONNECTION DIAGRAMS
N or D Package (Top View)
2
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Product Folder Link(s): UCC2884 UCC3884
UCC2884
UCC3884
www.ti.com............................................................................................................................................. SLUS160C–AUGUST 1999–REVISED NOVEMBER 2008
Block Diagram
Copyright © 1999–2008, Texas Instruments Incorporated
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UCC2884
UCC3884
SLUS160C–AUGUST 1999–REVISED NOVEMBER 2008............................................................................................................................................. www.ti.com
ELECTRICAL CHARACTERISTICS
Unless otherwise specified, these specifications apply for TA = -40°C to 85°C for the UCC2884, and 0°C to 70°C for the
UCC3884, CT = 220 pF, RON = 53 kΩ, ROFF = 38 kΩ, VOUT = VREF, VVS = 0 V, CSS = 2.5 nF, VDD = 11 V, Output no load,
TA = TJ.
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX
UNIT
5-V Reference
VREF
IREF = 0 mA
4.86
5
1
5.14
10
V
Line regulation
VDD = 10 V to 12 V
0 < IREF < 5 mA
VREF = 0 V
mV
mA
Load regulation
Short circuit
1
20
15
45
Oscillator
Accuracy
VOUT = VREF
360
200
4.8
400
230
5
440
260
5.2
0.4
kHz
V
Foldback frequency
CLKSYNC output high
CLKSYNC output low
CLKSYNC sink current
CLKSYNC source current
CLKSYNC input threshold
VOUT = 0.75 V
0.0
2.2
–0.2
3.0
CLKSYNC = 1 V
1.2
2.5
mA
V
CLKSYNC = 3 V
0.1
3.5
CLKSYNC from 5 V to 0 V (edge detect)
Error Amplifier
IB
Total bias current; regulating level
FB = COMP
–1
2.43
50
1
µA
V
FB voltage
2.5
90
2.57
AVO
dB
(1)
GBW
F = 100 kHz
2.5
5
MHz
Output source current
FB = 2.3 V, COMP = 2.5 V
FB = 2.7 V, VCOMP = 1 V
IO = 100 µA
–0.6
0.250
–1.2
1.5
0.3
3.1
mA
V
Output sink current
VOL
VOL
0.9
3.5
IO = –100 µA
2.7
PWM
Minimum duty cycle
Maximum duty cycle
FB = 3 V, CS = 0 V
FB = 0 V, CS = 0 V
0%
75%
78%
81%
Current Sense
Input bias current (CS)
3.0
µA
V
CS shutdown threshold
CS shutdown hysteresis
CS over current threshold
1.235
0.95
1.3
20
1
1.365
mV
V
1.05
Current/FAULT
Soft start charge current
Soft start discharge current
VOL
–10
10
–20
20
0
–30
30
µA
mV
V
50
Soft start complete threshold
Soft start restart threshold
3.6
0.4
4
4.4
0.6
0.5
(1) Specified by design. Not 100% tested in production.
4
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Product Folder Link(s): UCC2884 UCC3884
UCC2884
UCC3884
www.ti.com............................................................................................................................................. SLUS160C–AUGUST 1999–REVISED NOVEMBER 2008
ELECTRICAL CHARACTERISTICS (continued)
Unless otherwise specified, these specifications apply for TA = -40°C to 85°C for the UCC2884, and 0°C to 70°C for the
UCC3884, CT = 220 pF, RON = 53 kΩ, ROFF = 38 kΩ, VOUT = VREF, VVS = 0 V, CSS = 2.5 nF, VDD = 11 V, Output no load,
TA = TJ.
PARAMETER
Volt Second Clamp
TEST CONDITIONS
MIN
TYP
MAX
UNIT
VVS = 1.4 V, TA = 40°C to 85°C
VVS = 1.4 V, TA = 0°C to 70°C
VVS = 3.6 V, TA = –40°C to 85°C
VVS = 3.6 V, TA = 0°C to 70°C
VVS = 3.7 V
50%
52%
60%
57%
70%
67%
Duty cycle
20.5%
20.5%
–1
22.0%
22.0%
25.5%
23.5%
1
IB
µA
Output Stage
Output low saturation
IOUT = 100 mA
IOUT = –50 mA
0.5
0.5
0.9
0.9
1.9
1.2
70
Output low saturation
V
(2)
IOUT = 200 mA
UVLO output low saturation
Rise time
IOUT = 20 mA, VDD = 0 V
CL = 1 nF
0.7
50
30
ns
Fall time
CL = 1 nF
50
Undervoltage Lockout
Turn-on threshold voltage
Hysteresis
8.4
8.9
9.4
V
200
600
1000
mV
Startup Regulator
Regulated VDD voltage
VDD override threshold
Overall
9.5
10
10.5
10.7
V
VDD range
14.5
10
V
mA
µA
V
IDD (run)
f = 400 kHz
VDD = 5.4 V
IDD = 10 mA
2
100
12
5
IDD startup current
VDD clamp
250
15
13.5
(2) Specified by design. Not 100% tested in production.
Copyright © 1999–2008, Texas Instruments Incorporated
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PIN DESCRIPTIONS
CLKSYNC: An edge triggered active low TTL signal to this pin synchronizes the oscillator to an external clock.
When VOUT decreases below 3.0 V, the frequency foldback circuit is activated and the controller becomes
unsynchronized. When VOUT exceeds 3.0 V, the controller resynchronizes to the external clock.
COMP: The output of the voltage error amplifier used for compensation. The output is clamped to 3.0 V
minimum.
CS: Current sense input. This pin accepts a voltage proportional to converter inductor current. The voltage CS is
compared to the output of the compensated error amplifier to control the on-time of the switch. Voltage mode
control can be realized by driving this pin with fixed sawtooth ramp. Voltage feedforward is achieved by making
the peak of this ramp proportional to the input voltage.
CSS: A capacitor, CSS, to ground programs the soft-start time for the power-up sequence. This function is also
used when an overcurrent fault occurs. As CSS is charged, the PWM comparator uses the lowest of either the
voltage at CSS or the error amplifier output voltage to determine the duty cycle. The duty cycle, therefore, slowly
increases during the soft-start cycle. The faults that cause CSS to discharge and shutdown the controller are the
logical OR of VREF below 4.4 V or VDD below 8.8 V. If a fault is still present when CSS is discharged below 0.5
V, the supply remains off until the fault is cleared. The soft-start time is determined by:
CSS
tSS = 3.5´
ISS
where ISS is 20 µA. A current limit terminates the present cycle. It does not generate a soft start cycle.
CT: A capacitor, CT to ground, is charged and discharged creating the oscillator waveform. This waveform varies
between 1.5 V and 3.5 V. The operating frequency is determined by:
4.4
f =
R
ROFF
æ
ö
ON
CT ´
+
ç
÷
1.5
3.5
è
ø
The ratio of the time duration of the positive sloped portion of the CT voltage waveform to the period gives the
maximum duty cycle.
FB: The inverting input of the voltage amplifier used to sense the output voltage. The non-inverting input of the
error amplifier is internally connected to 2.5 V.
GND: The ground pin internally used for all the amplifiers and as the return for all resistor and capacitor
connections to the UCC3884.
GT: Used to drive an external depletion-mode MOSFET for the housekeeping power supply. The MOSFET is
turned off when the bootstrap winding voltage exceeds 10 V. There is 300 mV of hysteresis around the 10-V,
turn-off voltage to prevent oscillation. See Typical Application.
IOFF: A resistor, ROFF, to ground, programs the discharge current of the timing capacitor CT. This is a variable
discharge current which determines the negative slope of the oscillator voltage waveform at CT. The discharge
time is dependent on the voltage at the VOUT pin. The discharge current is given by:
VOUT
IOFF
=
ROFF
The VOUT pin is internally clamped to 3.5 V maximum.
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Product Folder Link(s): UCC2884 UCC3884
UCC2884
UCC3884
www.ti.com............................................................................................................................................. SLUS160C–AUGUST 1999–REVISED NOVEMBER 2008
ION: A resistor, RON, to ground programs the charge current of the timing capacitor, CT, which generates the
positive slope of the oscillator waveform. The charge time is constant and corresponds to the maximum output
on-time at OUT. The charge current equation is:
1.5V
ION
=
RON
When required the linear positive slope of the CT voltage could be buffered and used to provide slope
compensation into the CS pin.
OUT: The output of the controller. The peak source current is 0.5 A and the peak sink current is 1.0 A. The faults
listed under the CSS description turn off this output.
PGND: The power ground pin is used as the return for the output transistor drive stage.
VDD: The input voltage of the chip. A low ESR and ESL ceramic capacitor from this pin to GND should be used
to bypass internal switching transients.
VOUT: This pin accomplishes frequency foldback by controlling the discharge current for the oscillator CT
capacitor. A dc voltage proportional to the output voltage is connected to this pin. To startup with zero output
voltage the user should tie a resistor between VREF and VOUT. The value depends on the lowest desired
operating frequency. When VOUT decreases below 3.5 V the frequency decreases by reducing the discharge
current IOFF. When VOUT increases, the frequency increases by increasing the discharge current. The maximum
operating frequency occurs when VOUT = 3.5 V. The CT charge time is constant to assure a maximum output
duty cycle. This pin must be above 3.0 V to allow synchronization to occur.
VREF: This pin is the output of the 5-V regulated reference. Bypass this pin with a low ESR and ESL ceramic
capacitor (e.g., 0.47 µF).
VVS: Provides a programmable duty cycle clamp which is dependent upon the input voltage. A resistor divider
network reduces the input voltage supplied to VVS. The device determines the reciprocal of the voltage at VVS
and scales the result. The voltage is then compared to the oscillator waveform to clamp the duty cycle. The
purpose of this clamp is to reduce the likelihood of saturating the isolation transformer during unusual line or load
conditions.
Copyright © 1999–2008, Texas Instruments Incorporated
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UCC3884
SLUS160C–AUGUST 1999–REVISED NOVEMBER 2008............................................................................................................................................. www.ti.com
APPLICATION INFORMATION
Theory of Operation
The UCC3884 current-mode PWM controller contains a programmable oscillator which includes the ability to
synchronize multiple PWMs. The positive and negative sloped portions of the oscillator waveform (measured at
CT), have time intervals that are set by external resistors at ION and IOFF. The operating frequency is inversely
proportional to the timing capacitor. The negative sloped portion of the oscillator waveform is extended in time as
the measured output voltage decreases providing protection during output faults. The power supply output
voltage and the voltage from VREF are fed back to VOUT. When the output voltage decreases, the voltage at
VOUT also decreases. As VOUT decreases below 3.5 V, the operating frequency decreases. This reduction in
frequency allows the duty cycle to decrease below what the CS to OUT delay would otherwise permit. This is
referred to as frequency foldback. An output short circuit or overload causes the converter to enter the frequency
foldback mode. Synchronization to other controllers can only occur during normal operation, that is, when VOUT
is greater than 3.0 V.
GT is provided to turn off an external depletion-mode MOSFET after startup when the bootstrap winding exceeds
10 V. This depletion-mode MOSFET is used in the housekeeping section of the converter to simplify startup
biasing circuitry. The amplifier that drives this MOSFET has 300 mV of hysteresis to avoid oscillation during
power up.
An accurate programmable volt-second technique clamps the duty cycle. The duty cycle limit is inversely
proportional to input voltage and a resistor divider network is used to program the proportionality constant. At a
given input voltage and constant load, under closed loop control, the operating duty cycle is a fixed value. The
volt-second clamp duty cycle may then be set somewhat higher than this operating duty cycle. For other input
voltages, the volt-second clamp still exceeds the steady state operating duty cycle. This allows normal closed
loop operation of the converter. It is during a load transient (a fault such as a momentary short circuit) as the
error amplifier increases the duty cycle, that when the volt-second clamp accurately limits the maximum
volt-seconds. This ensures that the transformer does not saturate during a fault which can fail the power supply.
After the fault is removed the converter resumes closed loop control.
CSS is provided which allows the UCC3884 to be disabled with an external transistor. The increasing pulse width
at OUT during soft start should be programmed to be less than the pulse width of the duty cycle limit that the
frequency foldback circuitry creates. The frequency foldback circuit will be in effect during soft start since the
output voltage fed back to VOUT is less than 3.5 V. Designing the circuit in this fashion allows a proper startup
sequence.
The current sense feedback pin has an overcurrent protection feature which forces a soft start cycle only if the
device is not currently in a soft-start cycle. A 1-V bias at the PWM comparator’s non-inverting input and a reset
dominant PWM latch permit zero duty cycle operation.
The error amplifier has a wide gain-bandwidth product and its non-inverting input is internally set to 2.5 VDC.
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UCC3884
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Oscillator
The oscillator has charge and discharge currents programmed with resistors to ground from ION and IOFF
respectively, as seen on the Oscillator Block Diagram.(Figure 1). This generates a linear sawtooth waveform on
CT. Frequency foldback is accomplished by the level shifted output voltage controlling the VOUT voltage which
decreases the discharge current and the frequency.
Synchronization is accomplished by coupling the fastest oscillator CLKSYNC signal as shown on the Oscillator
Synchronization Diagram (Figure 2). The fastest (master) CLKSYNC pin couples a negative pulse into the slower
(slave) CLKSYNC pins forcing the slaves’ CT pins to quickly discharge as shown on the Oscillator Waveform
diagram (Figure 3).
VREF
1.5V
–
ION 11
+
CLK
3.5V
1.5V
S
R
Q
Q
CT 10
VREF
6
CLKSYNC
VOUT 13
IOFF 12
+
–
3.0V
14
3.5V
3V
SYNCEN
SYNCEN
8.8X
Figure 1. UCC3884 Oscillator
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Synchronization Techniques
The following explains two synchronization techniques:
1. Initially Undefined Master If the user does not care which unit is the master, then the oscillator frequencies
are designed as accurate as necessary and one unit becomes the master and synchronize the remaining
units. The user never knows exactly which unit will be the master upon power up.
2. User-Defined Master If the user does care which unit is the master, a unit should be identified as the
master, and the frequency and maximum duty cycle clamp should be programmed accordingly. The ROFF
resistor which programs the slave units oscillator discharge ramp should be between 50% and 100% of the
ROFF resistor which programs the master. This ensures that if a slave unit tries to synchronize the master,
the master frequency will still be faster than the slave frequency and the master synchronizes all the
remaining units.
Figure 2. Oscillator Waveforms
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Figure 3. Typical Application
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