TI UCC3858

UCC1858
UCC2858
UCC3858
High Efficiency, High Power Factor Preregulator
PRELIMINARY
FEATURES
DESCRIPTION
• Programmable PWM Frequency
Foldback for Higher Efficiency at Light
Loads
The UCC3858 provides all of the control functions necessary for active
power factor corrected preregulators which require high efficiency at low
power operation. The controller achieves near unity power factor by
shaping the AC input line current waveform to correspond to the AC input
line voltage using average current mode control.
• Leading Edge PWM for Reduced
Output Capacitor Ripple Current
• Controls Boost PWM to Near Unity
Power Factor
• World Wide Operation without
Switches
• Accurate Power Limiting
• Synchronizable Oscillator
• 100µA Startup Supply Current
• Low Power BCDMOS
• 12V to 18V Operation
The operation of the UCC3858 closely resembles that of previously designed Unitrode PFC parts with additional features to allow higher efficiency boost converter operation at light loads. This is accomplished by
linearly scaling back the PWM frequency when the output of the voltage
error amplifier drops below a predetermined user programmable level indicating a light load condition. The frequency is scaled back by reducing
the charging current for the CT ramp (in proportion to the output power),
and increasing the dead time. There is also an instantaneous reset input
to pull the IC out of foldback mode quickly when the load comes back up.
The PWM technique used in the UCC3858 is leading edge modulation.
When combined with the more conventional trailing edge modulation on
the downstream converter, this scheme offers the benefit of reduced ripple current on the bulk storage capacitor. The oscillator is designed for
easy synchronization to the downstream converter. A simple synchronization scheme can be implemented by connecting the PWM output of
the downstream converter to the SYNC pin.
(continued)
BLOCK DIAGRAM
UDG-96191-1
03/99
UCC1858
UCC2858
UCC3858
CONNECTION DIAGRAM
ABSOLUTE MAXIMUM RATINGS
DIP-16, SOIC-16 (TOP VIEW)
J, N, DW Packages
Supply Voltage VDD . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 18V
Gate Drive Current
Continuous . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 0.2A
Pulsed . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 500mA
Input Current IAC . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 200mA
Power Dissipation. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1W
Storage Temperature . . . . . . . . . . . . . . . . . . . −65°C to +150°C
Junction Temperature . . . . . . . . . . . . . . . . . . . −55°C to +150°C
Lead Temperature (Soldering, 10 Sec.). . . . . . . . . . . . . +300°C
Analog Inputs
Maximum Forced Voltage . . . . . . . . . . . . . . . . –0.3V to 11V
IAC
1
16
GND
CRMS
2
15
OUT
MOUT
3
14
VDD
VREF
4
13
RT
CA–
5
12
CT
CAO
6
11
FBM
VA–
7
10
SYNC
VAO
8
9
FBL
Unless otherwise indicated, voltages are reference to ground and currents are positive into, negative out of the specified terminal. Pulsed is
defined as a less than 10% duty cycle with a maximum duration of
500ns. Consult Packaging Section of Databook for thermal limitations
and considerations of packages.
DESCRIPTION (cont.)
Unitrode’s BCDMOS process simplify the bootstrap
supply design as well as minimize losses in the control
circuit. A transconductance voltage error amplifier allows
output voltage sensing for internal overvoltage protection.
Controller improvements include an onboard peak detector for the input line RMS voltage, an integrated
overcurrent shutdown, overvoltage shutdown and significantly lower quiescent operating current. The peak detector eliminates an external 2-pole low pass filter for
RMS detection. This simplifies the converter design as
well as providing an approximate 6X improvement in input line transient response. The current signal is extracted from the current error amplifier input to provide a
cycle-by-cycle peak current limit. Low startup and operating currents which are achieved through the use of
Additional features include: undervoltage lockout for reliable off-line startup, a precision 7.5V reference, and a
precision RMS detection and signal conditioning circuit.
Chip shutdown can be attained by bringing the FBL pin
below 0.5V.
ELECTRICAL CHARACTERISTICS: Unless otherwise stated, these specifications apply for TA = 0°C to 70°C for the
UCC3858, –40°C to +85°C for the UCC2858, and –55°C to +150°C for the UCC1858, VVDD = 12V, RT = 24k, CT = 330pF, RFBM =
96k, IIAC = 100µA, TA = TJ.
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX UNITS
Overall
Supply Current, Off
VCAO, VVAO = 0V, VDD = UVLO – 0.3V
Supply Current, On
FBL = 0V
VDD Turn-On Threshold
100
250
µA
2
3.5
5
mA
12
13.5
15.5
V
3.2
3.5
3.8
V
3
3.05
V
0.14
0.16
V
–0.5
–1
µA
VDD Turn-Off Threshold
10
UVLO Hysteresis
V
Voltage Amplifier
Input Voltage
TA = 25°C
2.95
Over Voltage Protection
Volts Above VA– Input Voltage
0.12
VA– Bias Current
Open Loop Gain
VOUT = 2V to 5V
45
VAO High
Load = –25µA
5.7
VAO Low
Load = 25µA
Output Source Current
VVA– = 2.8V
Output Sink Current
VVA– = 3.2V
50
Transconductance
IOUT = ± 50µA
400
2
50
dB
6
6.3
V
0.3
0.5
V
–50
µA
µA
600
1000
µS
UCC1858
UCC2858
UCC3858
ELECTRICAL CHARACTERISTICS: Unless otherwise stated, these specifications apply for TA = 0°C to 70°C for the
UCC3858, –40°C to +85°C for the UCC2858, and –55°C to +150°C for the UCC1858, VVDD = 12V, RT = 24k, CT = 330pF, RFBM =
96k, IIAC = 100µA, TA = TJ.
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX UNITS
Current Amplifier
Input Offset Voltage
VCM = 0V, VCAO = 3V
–3
0
Input Bias Current
VCM = 0V, VCAO = 3V
–6.5
–5
Input Offset Current
VCM = 0V, VCAO = 3V
–0.5
0.0
Open Loop Gain
VCM = 0V, VCAO = 2V to 5V
80
90
CMRR
VCM = 0V to 1.5V, VCAO = 3V
65
80
CAO High
VCA– = 0V, VMOUT = 1V, IL = –50µA
6.5
7
7.5
V
CAO Low
VCA– = 1V, VMOUT = 0V, IL = 1mA
0.2
0.3
V
Maximum Output Source Current
–130
–150
3
mV
µA
0.5
µA
dB
dB
µA
Voltage Reference
Output Voltage
Load Regulation
IREF = 0mA, TA = 25°C
7.313
7.5
7.688
V
Over Temperature, UCC3858
7.294
7.5
7.707
V
Over Temperature, UCC2858, UCC1858
7.239
7.5
7.762
V
3
5
mV
IREF = 0mA to 2mA
Line Regulation
VDD = 12V to 16V
30
Short Circuit Current
VREF = 0V
35
50
mA
mV
100
110
kHz
Oscillator
Initial Accuracy
TA = 25°C
Voltage Stability
VDD = 12V to 16V
Total Variation
Line, Temperature
90
80
1
%
120
kHz
Ramp Amplitude (p-p)
Oscillator Free Running, VAO = 5.5V
3.3
3.5
3.7
V
Ramp Peak Voltage
Oscillator Free Running, VAO = 5.5V
4.4
4.6
4.8
V
(VCA–)–VMOUT
350
450
550
mV
100
200
mV
Peak Current Limit
PKLMT Threshold Voltage
PKLMT Hysteresis
PKLMT Propagation Delay
1
µs
µA
Multiplier Section
High Line, Low Power
IAC = 100µA, VCRMS = 3.5V, VAOUT = 1.25V
1
High Line, High Power
IAC = 100µA, VCRMS = 3.5V, VAOUT = 5.5V
15
µA
Low Line, Low Power
IAC = 20µA, VCRMS = 0.75V, VAOUT = 1.25V
4
µA
Low Line, High Power
IAC = 20µA, VCRMS = 0.75V, VAOUT = 5.5V
64
µA
IAC Limited
IAC = 20µA, VCRMS = 0.4V, VAOUT = 5.5V
64
µA
Gain Constant
IAC = 100µA, VCRMS = 3.5V, VAOUT = 5.5V
2.5
1/V
Zero Current
IAC = 20µA, VCRMS = 0.75V, VAOUT = 5.5V (Note 1)
0
µA
IAC =100µA, VCRMS = 3.5V, VAOUT = 5.5V (Note 1)
0
µA
IAC = 20µA, VCRMS = 0.75V, VAOUT = 5.5V
45
µW
–100
nA
0.5
V
Power Limit (VCRMS • IMO)
PWM Frequency Foldback
FBL Input Current
–500
FBL Output Disable
Foldback Minimum Frequency
RFBM = 100k
FBM Foldback Override
3
25
30
kHz
1.5
1.75
V
UCC1858
UCC2858
UCC3858
ELECTRICAL CHARACTERISTICS: Unless otherwise stated, these specifications apply for TA = 0°C to 70°C for the
UCC3858, –40°C to +85°C for the UCC2858, and –55°C to +150°C for the UCC1858, VVDD = 12V, RT = 24k, CT = 330pF, RFBM =
96k, IIAC = 100µA, TA = TJ.
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX UNITS
Gate Driver
Ω
Pull Up Resistance
IOUT = 100mA
Pull Down Resistance
IOUT = –100mA
3.5
Ω
Output Rise Time
CLOAD = 1nF, RS = 10Ω
25
ns
Output Fall Time
CLOAD = 1nF, RS = 10Ω
20
ns
7
Note1: MOUT current with contributions form CA+ and peak limit level shift subtracted out.
PIN DESCRIPTIONS
CA–: (Current Amplifier Inverting Input) This input and
the non-inverting input MOUT remain functional down to
GND.
capacitor discharge current also returns to this pin, so
the lead from CT to GND should be as short and direct
as possible.
CAO: (Current Amplifier Ouput) Output of a wide bandwidth amplifier that senses line current and commands
the pulse width modulator (PWM) to force the correct current. This output can swing close to GND, allowing the
PWM to force zero duty cycle when necessary.
IAC: (Input AC Current) This input to the analog multiplier
is a current. The multiplier is tailored for very low distortion from this current input (IIAC) to MOUT. Requires
some bypassing to GND for noise filtering (<470pF).
MOUT: (Multiplier Output) The output of the analog multiplier and the non-inverting input of the current amplifier
are connected together at MOUT. As the multiplier output
is a current, this is a high impedance input so the amplifier can be configured as a differential amplifier to reject
ground noise. The voltage at this pin is also used to implement peak current limiting.
CRMS: (RMS Measurement Capacitor) A capacitor connected between CRMS and GND enables averaging of
the AC line voltage over a half cycle. IAC current is internally mirrored to provide charging current for CRMS.
CT: (Oscillator Timing Capacitor) A capacitor from CT to
GND will set the free-running PWM oscillator frequency
according to:
f =
OUT: (Gate Drive Output) The output of the PWM is a totem pole MOSFET gate driver. A series gate resistor of
at least 5Ω is recommended to prevent interaction between the gate impedance and the output driver that
might cause the gate drive to overshoot excessively.
0.814
RT • CT
FBL: (Frequency Foldback Level Select) Selects the level
of the voltage error amplifier output at which frequency
foldback begins. A chip shutdown can be attained by
bringing the foldback level pin to below 0.5V.
RT: (Oscillator Timing Resistor) A resistor from RT to
GND is used to program oscillator discharge current.
SYNC: (Oscillator Synchronization Input) Allows the PFC
to be synchronized to a trailing edge modulator in the
DC-DC stage. A synchronization pulse can be generated
from the positive output edge of the downstream regulator and applied to this pin. The internal clock is reset
(charged up) on the rising edge of the SYNC input.
FBM: (Minimum Frequency Reference) A resistor between this pin and VREF is used to set the minimum frequency during foldback mode. Once the value of RT and
CT are determined, use
R FBM =
0.857
− RT
CT • fMIN
VA–: (Voltage Amplifier Inverting Input) This pin is normally connected to the boost converter output through a
divider network. It also is an input to the overvoltage
comparator where by the output is terminated if this pin’s
voltage exceeds 3.15V.
to find the value of RFBM which will set the minimum
foldback frequency to fMIN. This pin also incorporates a
foldback override which enables the part to return quickly
to normal operating mode when the load comes back up.
To override foldback mode, force this pin below 1.5V with
an open collector.
VAO: (Voltage Amplifier Output) Output of the
transconductance amplifier that regulates output voltage.
The voltage amplifier output is internally limited to approximately 6V for power limiting. It is also used to determine the frequency foldback mode. Compensation
network is connected from this pin to GND.
GND: (Ground) All voltages measured with respect to
ground. VDD and VREF should be bypassed directly to
GND with a 0.1µF or larger ceramic capacitor. The timing
4
UCC1858
UCC2858
UCC3858
PIN DESCRIPTIONS (cont.)
VREF: (Reference Voltage) VREF is the output of an accurate 7.5V voltage reference. This output is capable of
delivering 10mA to peripheral circuitry and is internally
short circuit current limited. VREF is disabled and will remain at 0V when VVDD is low. Bypass VREF to GND with
a 0.1µF or larger ceramic capacitor for best stability.
VDD: (Positive Supply Voltage) Connect to a stable
source of at least 20mA between 13V and 17V for normal
operation. Bypass VDD directly to GND to absorb supply
current spikes required to charge external MOSFET gate
capacitance. To prevent inadequate gate drive signals,
the output devices will be inhibited unless VVDD exceeds
the upper undervoltage lockout voltage threshold and remains above the lower threshold.
APPLICATION INFORMATION
The UCC3858 is designed to optimize the implementation of power factor corrected boost converters in low to
medium power applications where light load efficiency is
critical. While basic configuration of the UCC3858 is similar to the industry standard UC3854 series controllers,
several distinguishing features have been added. A typical application circuit is shown along with a diagram
showing how the UCC3858 can be used with the downstream converter to achieve optimum performance.
When VAO falls below the threshold level set by FBL, the
oscillator goes into frequency foldback mode and disables synchronization. The frequency foldback is
achieved by reducing the oscillator charging current as
the power level (and VAO voltage) falls. As shown in Fig.
2, the difference between VAO and FBL regulates current ICsub which subtracts the current available for charging CT. The effective charge current into the capacitor is
given by (ICHnom - ICsub). To avoid converter operation in
the low frequency range (e.g. audio), the charge current
should not be allowed to go very low. Minimum frequency
of the controller is programmed by the current IMIN flowing into pin FBM which sets the minimum charging current. The value of RFBM to set the desired minimum
frequency is given by:
Chip Bias Supply and Startup
The UCC3858 is implemented using Unitrode’s
BCDMOS process allowing minimal startup (60µA typical) and operating (3.5mA typical) supply currents. This
results in significantly lower power consumption in the
trickle charge resistor used to startup the IC, increasing
the system efficiency at light loads. Lower supply currents, coupled with the wide undervoltage lockout hysteresis (13.75V on, 10V off) provide the opportunity to
operate both stages from the same startup and bootstrap
supply as shown in the typical application drawing.
R FBM =
The oscillator of the UCC3858 is set up to operate either
synchronously with the downstream converter or as a
stand alone oscillator. A simplified block diagram of the
oscillator and associated circuitry is shown in Fig. 2 and
the related waveforms are shown in Fig. 3a - 3c. A rising
edge at the SYNC pin initiates the clock cycle by charging up the CT pin with a nominal internal current of
ICHnom (=19 •IDIS). Once the high threshold of the ramp
(4.5V) is crossed, the internal latch is set and the CT pin
starts discharging at a rate (IDIS=3/RT) set by the resistor
on the RT pin. In the absence of a SYNC pulse, CT discharges all the way to the ramp low threshold (1V) and
that sets the free running frequency of the oscillator as
given by equation 1. In applications where synchronization is used, the RT, CT values should be chosen so that
the free running frequency is always lower than the synchronization frequency.
19
3
1
•
•
20 3 . 5 RT • CT
(2)
Fig. 4 shows the characteristic curves for the frequency
foldback. When the converter comes out of the low
power mode, the time taken to restore normal mode operation (return to nominal or synchronized frequency operation) must be minimized. Given that the voltage error
amplifier response is very slow in PFC circuits, the VAO
pin change is not the best indicator of change in load
conditions. UCC3858 provides a solution where the normal mode can be restored instantaneously when FBM is
pulled below 1.5V. A typical interface would involve the
output of the error amplifier of the downstream converter
(with proper buffering and filtering) driving an npn switch
that pulls FBM down to GND. The buffer and filter should
ensure that the switch is turned on only when the error
amplifier of downstream converter is saturated high for a
preset duration indicating a droop in output voltage from
increased load. The FBM input can also be permanently
pulled low to disable the frequency foldback mode completely, while still using the other features of UCC3858.
FBL pin also acts as a chip disable input when it is
brought below 0.5V.
Oscillator and Frequency Foldback at Light Loads
f =
3
1
•
– RT
3.5 fMIN • CT
(1)
5
UCC1858
UCC2858
UCC3858
APPLICATION INFORMATION (cont.)
UDG-97120-1
* Pins 4, 9 and 14 need good bypassing to GND for noise immunity. Capacitors C2, C3 and C23 should each consist of a combination of ceramic (0.47µF) and tantalum (4.7µF) capacitors for best results.
* * L1 can be fabricated with an Allied Signal Amorphous Core MP4510PFC, using a 100 turn (AWG 18) primary and 5 turn secondary. Alternatively, a gapped Ferrite Choke can be used. (Coiltronics CTX-08-13679)
Figure 1. UCC3858 Typical application circuit.
6
UCC1858
UCC2858
UCC3858
APPLICATION INFORMATION (cont.)
UDG-97121-1
Figure 2. Oscillator block diagram.
4.75V
VCAO
SYNC
VCT
4.75V
VCAO
VCT
>1V
>1V
VOUT
VOUT
BOOST
DIODE
CURRENT
BOOST
DIODE
CURRENT
TS
TS
Figure 3a. Oscillator timing waveforms synchronized
to buck (DC/DC) PWM.
Figure 3b. Oscillator timing waveforms stand alone
operation.
7
UCC1858
UCC2858
UCC3858
APPLICATION INFORMATION (cont.)
100
VCT
% NOMINAL FREQUENCY
4.5V
VCAO
>1V
SLOPE=
TS
ICH
CT
VOUT
80
RFBM = 10k
60
RFBM = 25k
40
20
0
RFBM = 100k
–1
–2
–3
–4
–5
–6
FBL = VAO (V)
CLK
(RT = 24k, C T = 330pF, NOMINAL FREQUENCY 100kHz)
Figure 4. Frequency foldback characteristics.
BOOST
DIODE
CURRENT
Figure 3c. Frequency foldback mode.
Capacitor Ripple Reduction
For a power system where the PFC boost converter is
followed by a DC-DC converter stage, there are benefits
to synchronizing the two converters. In addition to the
usual advantages such as noise reduction and stability,
proper synchronization can significantly reduce the ripple
currents in the boost circuit’s output capacitor. Fig. 5
helps illustrate the impact of proper synchronization by
showing a PFC boost converter together with the simplified input stage of a forward converter. The capacitor current during a single switching cycle depends on the
status of the switches Q1 and Q2 and is shown in Fig. 6.
It can be seen that with a synchronization scheme that
maintains conventional trailing edge modulation on both
converters, the capacitor current ripple is highest. The
greatest ripple current cancellation is attained when the
overlap of Q1 off-time and Q2 on-time is maximized. One
method of achieving this is to synchronize the turn-on of
the boost diode (D1) with the turn-on of Q2. This approach implies that the boost converter’s leading edge is
pulse width modulated while the forward converter is
modulated with traditional trailing edge PWM. The
UCC3858 is designed as a leading edge modulator with
easy synchronization to the downstream converter to facilitate this advantage. Table 1 compares the ICBrms for
D1/Q2 synchronization as offered by UCC3858 vs. the
ICBrms for the other extreme of synchronizing the turn-on
of Q1 and Q2 for a 200W power system with a VBST of
385V.
UDG-97130-1
Figure 5. Simplified representation of a 2-stage PFC
power supply.
UDG-97131
Switch Sync
Trailing-Edge PWM for
both Boost and Buck
Inverted Switch Sync
Leading-Edge Boost PWM
Trailing-Edge Buck PWM
Figure 6. Timing waveforms for synchronization
scheme.
8
UCC1858
UCC2858
UCC3858
APPLICATION INFORMATION (cont.)
Table I. Effects of Sychronization on Boost
Capacitor Current
D(Q2)
0.35
0.45
VIN = 85V
VIN = 120V
VIN =
Q1/Q2 D1/Q2 Q1/Q2 D1/Q2 Q1/Q2
1.491A 0.835A 1.341A 0.663A 1.024A
1.432A 0.93A 1.276A 0.664A 0.897A
VCRMS =
240V
D1/Q2
0.731A
0.614A
I AC pk
2 • ω • C RMS
VCRMS (pk ) =
Table 1 illustrates that the boost capacitor ripple current
can be reduced by about 50% at nominal line and about
30% at high line with the synchronization scheme facilitated by the UCC3858. The output capacitance value can
be significantly reduced if its choice is dictated by ripple
current or the capacitor life can be increased as a result.
In cost sensitive designs where hold-up time is not critical, this is a significant advantage.
(3a)
• (1 – cos ω t )
(3b)
I AC pk
ω • C RMS
LINE
VCRMS
ADC
HOLD
An alternative method of synchronization to achieve the
same ripple reduction is possible. In this method, the
turn-on of Q1 is synchronized to the turn-off of Q2. While
this method yields almost identical ripple reduction and
maintains trailing edge modulation on both converters,
the synchronization is much more difficult to achieve and
the circuit can become susceptible to noise as the synchronizing edge itself is being modulated.
RAC
IAC
1
A
B
VAO
A•B
C
C
CRMS
2
CRMS
A
D
4 BIT
WORD
REGISTER
MULTI
DAC
(X2)
Reference Signal (IMULT) Generation
Like the UC3854 series, the UCC3858 has an Analog
Computation Unit (ACU) which generates a reference
current signal for the current error amplifier. The inputs to
the ACU are (signals proportional to) instantaneous line
voltage, input voltage RMS information and the voltage
error amplifier output. Unlike prior techniques of RMS
voltage sensing, UCC3858 employs a patent pending
technique to simplify the RMS voltage generation and
eliminate performance degradation caused by the prior
techniques. With the novel technique (shown in Fig. 7),
need for external two pole filter for VRMS generation is
eliminated. Instead, the IAC current is mirrored and used
to charge an external capacitor (CRMS) during a half cycle. The voltage on CRMS takes the integrated sinusoidal
shape and is given by equation 3. At the end of the halfcycle, CRMS voltage is held and converted into a 4-bit
digital word for further processing in the ACU. CRMS is
discharged and readied for integration during the next
half cycle. The advantage of this method is that the second harmonic ripple on the VRMS signal is virtually eliminated. Such second harmonic ripple is unavoidable with
the limited roll-off of a conventional 2-pole filter and results in a 3rd harmonic distortion in the input current signal. The dynamic response to the input line variations is
also improved as a new VRMS signal is generated every
cycle.
Figure 7. Novel circuit for RMS signal generation.
For proper operation, IACpk should be selected to be
100µA at peak line voltage. For universal input voltage
with peak value of 265 VAC, this means RAC = 3.6M. The
noise sensitivity of the IC requires a small bypass capacitor for high frequency noise filtering. The value of this capacitor should be limited to 330pF maximum. The VCRMS
value should be approximately 1V at the peak of low line
(80 VAC) to minimize any digitization errors. The peak
value of VCRMS at high line then becomes 3.5V. The desired CRMS can be calculated from equation 3 to be 90nF
for 50Hz line and 75nF for 60Hz line.
The multiplier output current is given by equation (4) with
K=0.33.
I MULT =
(VVAO – 1) • I AC • K
VCRMS
(4)
2
The multiplier peak current is limited to 200µA and the
selected values for IAC and VCRMS should ensure that
the current is within this range. Another limitation of the
multiplier is that IMULT can not exceed two times the IAC
current, limiting the minimum voltage on VCRMS.
9
UCC1858
UCC2858
UCC3858
APPLICATION INFORMATION (cont.)
The discrete nature of the RMS voltage feedforward
means that there are regions of operation where the input voltage changes, but the VRMS value fed into the multiplier does not change. The voltage error amplifier
compensates for this by changing its output to maintain
the required multiplier output current. When the output of
the ADC changes, there is a jump in the output of the error amplifier. There is a resultant shift in the foldback frequency if the converter is at light load. However, the
impact of this change is minimal on the overall converter
operation.
Current Amplifier Set-up
The multiplier is set-up first by choosing the VRMS range.
The maximum multiplier output is at low line, full load
conditions. The inductor peak current also occurs at the
same point. The multiplier terminating resistor can be determined using equation 5.
R MULT =
ILPK • R SENSE
I MULT PK
The peak current limiting function provided by the
UCC3858 is integrated into MOUT. The signal on MOUT
is normally maintained at 0V as the (IMULT • RMULT) cancels the voltage drop across the sense resistor with
closed loop operation. During short circuit or transient
startup conditions, the multiplier current can not fully cancel the voltage drop across RSENSE and the voltage at
MOUT drops below 0V. The internal peak current limit is
activated when MOUT drops below –0.5V. The peak current limit at any operating point is given by:
Another key consideration with the RMS voltage scheme
is that it relies on the zero-crossing of the IAC signal to be
effective. At very light loads and high line conditions, the
rectified AC does not quite reach zero if a large capacitor
is being used for filtering on the rectified side of the
bridge. In such instances, the feedforward effect does not
take place and the controller functionality is lost. For
UCC3858, the IAC current should go below 10µA for the
zero crossing detection to take place. It is recommended
that the capacitor value be kept low enough for the light
load operation or the feedforward be derived directly from
the AC side of the input bridge as shown in the typical
applications circuit.
I LIM =
I MULT • R MULT + 0.5
R SENSE
(6)
The current amplifier can be compensated using previously presented techniques, (Application Note U- 134),
summarized here. A simplified high frequency model for
inductor current to duty cycle transfer function is given
by:
Gate Drive Considerations
The gate drive circuit in UCC3858 is designed for high
speed power switch drive. It consists of low impedance
pull-up and pull-down DMOS output stages. When operating with high bias voltages, in order to stay within the
SOA of the DMOS output stages, it is recommended that
the gate drive current be limited to 0.5A peak with the
use of external gate resistor. Please see the characteristic curve in Fig. 8 for determining the required external resistance.
G id
∧
i L VO
(s ) =
=
∧ sL
d
(7)
The gain of the current feedback path at the frequency of
interest (crossover) is given by:
∧
d
∧
40
iL
30
RS(Ω)
(5)
= R SENSE •
RZ
1
•
R I V SE
(8)
Where VSE is the ramp amplitude (p-p) which is 3.5V for
UCC3858. Combining equations 7 and 8 yields the loop
gain of the current loop and equating it to 1 at the desired crossover frequency can result in a design value for
RZ. The current loop crossover frequency selected using
conventional trade offs. However, it should be ensured
that the current-loop is stable at the minimum switching
frequency under foldback conditions.
20
10
0
10
12
14
16
18
20
VDD(V)
Figure 8. Reguired series gate resistance as a
function of supply voltage.
10
UCC1858
UCC2858
UCC3858
APPLICATION INFORMATION (cont.)
Voltage Amplifier Set-up
The voltage amplifier in UCC3858 is a transconductance
type amplifier to allow output voltage monitoring for an
overvoltage condition. The gain of the amplifier, given by
APPLICATION INFORMATION (continued)
UDG-96192-1
Figure 9. Use of the UCC3858 in a two stage converter to optimize performance.
UNITRODE CORPORATION
7 CONTINENTAL BLVD. • MERRIMACK, NH 03054
TEL. (603) 424-2410 • FAX (603) 424-3460
11
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