MPS MP6001DN

TM
MP6001
Monolithic Flyback/Forward
DC-DC Converter
The Future of Analog IC Technology
TM
INITIAL RELEASE – SPECIFICATIONS SUBJECT TO CHANGE
DESCRIPTION
FEATURES
The MP6001 is a monolithic Flyback/Forward
DC-DC converter which includes a 150V power
switch and is capable of delivering up to 15W
output power. It can also be used for boost and
SEPIC applications.
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The MP6001 uses the fixed-frequency peak
current mode primary controller architecture. It
has an internal soft-start, auto-retry, and
incorporates over current, short circuit, and
over-voltage protection. The MP6001 can also
skip cycles to maintain zero load regulation.
It has a direct optocoupler interface which
bypasses the internal error amplifier when an
isolated output is desired.
Integrated 0.9Ω 150V Power Switch
Cycle-by-Cycle Current Limiting
Programmable Switching Frequency
Duty Cycle Limiting with Line Feed Forward
Integrated 100V Startup Circuit
Internal Slope Compensation
Disable Function
Built-in Soft-Start
Line Under Voltage Lockout
Line Over Voltage Protection
Auto-Restart for Opened/Shorted Output
Zero Load Regulation
Thermal Shutdown
APPLICATIONS
The MP6001 is ideal for telecom applications,
and is available in a compact, thermally
enhanced SO8 package with an exposed pad.
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Telecom Equipment
VoIP Phones, Power over Ethernet (PoE)
Distributed Power Conversion
“MPS” and “The Future of Analog IC Technology” are Trademarks of Monolithic
Power Systems, Inc.
TYPICAL APPLICATION
Efficiency vs
Load Current
VOUT
+VIN
5V @ 3A
D2
B330A
36V~72V
D1
1N4148
EFFICIENCY (%)
6
3
4
SW
LINE
VIN
VCC
MP6001
FB
COMP
VIN = 36V
80
PC357
2
90
GND
RT
8
7
1
C3
5
10nF
R3
70
60
VIN = 48V
50
VIN = 75V
40
30
20
TL431
VOUT = 5V
10
-VIN
0
MP6001_TAC_S01
0
0.5
1.0
1.5
2.0
2.5
3.0
LOAD CURRENT (A)
MP6001-EC01
MP6001 Rev. 0.91
4/5/2006
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TM
MP6001 – MONOLITHIC FLYBACK/FORWARD DC-DC CONVERTER
INITIAL RELEASE – SPECIFICATIONS SUBJECT TO CHANGE
ABSOLUTE MAXIMUM RATINGS (1)
PACKAGE REFERENCE
GND
1
8
SW
LINE
2
7
VIN
VSW............................................. –0.5V to +180V
VIN ............................................. –0.3V to +120V
All Other Pins.............................. –0.3V to +6.5V
Junction Temperature...............................150°C
Lead Temperature ....................................260°C
Storage Temperature ..............–65°C to +150°C
FB
3
6
VCC
Recommended Operating Conditions
COMP
4
5
RT
TOP VIEW
Supply Voltage VCC ........................... 4.5 V to 6V
Output Voltage VSW.................... –0.5V to +150V
Input Voltage VIN ........................ –0.3V to +100V
Operating Temperature .............–40°C to +85°C
MP6001_PD01_SOIC8N
Part Number*
Package
Temperature
MP6001DN
SOIC8N
–40°C to +85°C
*
(2)
For Tape & Reel, add suffix –Z (eg. MP6001DN–Z)
For RoHS compliant packaging, add suffix –LF (eg. MP6001DN–LF–Z)
Thermal Resistance
(3)
θJA
θJC
SOIC8N (Exposed Pad) ......... 50 ...... 10... °C/W
Notes:
1) Exceeding these ratings may damage the device.
2) The device is not guaranteed to function outside of its
operating conditions.
3) Measured on approximately 1” square of 1 oz copper.
ELECTRICAL CHARACTERISTICS
VCC = 5.0V, VLINE = 1.8V, RT = 10k, TA = +25°C, unless otherwise noted.
Parameter
Quiescent Supply Current
Line OV Threshold Voltage
Line OV Hysteresis
Line UV Threshold Voltage
Line UV Hysteresis
VCC Upper Threshold Voltage
VCC Lower Threshold Voltage
Feedback Voltage
Feedback Input Current
Error Amplifier Gain Bandwidth (4)
Error Amplifier DC Gain (4)
Comp Output Source Current
Comp Output Sink Current
Switch-On Resistance
Switch Leakage Current
Minimum Oscillating Frequency
Maximum Oscillating Frequency
Thermal Shutdown (4)
Thermal Shutdown Hysteresis (4)
Current Limit (4)
Startup Current
Symbol Condition
ICC
1.2V < VLINE < 3.2V, VFB = 1.3V
VCC = 5.0V
VCC = 5.0V
VCC = 5.0V
VCC = 5.0V
VFB
IFB
GBW
AV
IOH
IOL
RON
ILK
FMIN
FMAX
ILIM
Ist
Min
2.85
1.16
5.75
4.30
1.16
VFB = 1.2V
Typ
1.0
3
300
1.21
100
6.0
4.50
1.21
50
1
60
VFB = 1.0V, VCOMP = 0.5V
VFB = 1.4V, VCOMP = 2.5V
VSW = 0.1V
VSW = 150V
RT = 100k
RT = 10k
VIN = 20V, VCC = 4.0V
2
2
0.9
1
55
550
150
30
2
3
Max
1.5
3.15
1.26
6.25
4.70
1.26
Units
mA
V
mV
V
mV
V
V
V
nA
MHz
dB
mA
mA
Ω
µA
KHz
KHz
°C
°C
A
mA
Note:
4) Guaranteed by design, not production tested.
MP6001 Rev. 0.91
4/5/2006
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MP6001 – MONOLITHIC FLYBACK/FORWARD DC-DC CONVERTER
INITIAL RELEASE – SPECIFICATIONS SUBJECT TO CHANGE
PIN FUNCTIONS
Pin #
1
2
3
4
5
6
7
8
Name Description
GND
LINE
Ground. Power return and reference node.
UV/OV Set Point. Short to ground to turn the controller off.
Regulation Feedback Input. Inverting input of the error amplifier. The non-inverting is internally
FB
connected to 1.2V
COMP Error Amplifier Output.
Oscillator Resistor and Synchronous Clock Pin. Connect an external resistor to GND for
RT
oscillator frequency setting. It can be used as a synchronous input from external oscillator clock.
VCC Supply Bias Voltage.
VIN High Voltage Startup Circuit Supply.
Output Switching Node. High voltage power N-Channel MOSFET drain output. The internal
SW
start bias current is supplied from this pin.
MP6001 Rev. 0.91
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MP6001 – MONOLITHIC FLYBACK/FORWARD DC-DC CONVERTER
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TYPICAL PERFORMANCE CHARACTERISTICS
VIN = 48V, VOUT = 5V, TA = +25ºC, unless otherwise noted.
Steady State Test
VIN = 48V, VOUT = 5V, IOUT = 2.7A
Synchronize Programmable
Oscillator
Synchronize Programmable
Oscillator
fSW = 54KHz, 60KHz of SYNC signal is
applied to RT pin.
fSW = 54KHz, 500KHz of SYNC signal is
applied to RT pin.
VOUT
2V/div.
VOUT
2V/div.
VOUT
AC Coupled
50mV/div.
VSW
20V/div.
VSW
100V/div.
VSW
20V/div.
VSYNC
2V/div.
ITRANS
1A/div.
VSYNC
2V/div.
ITRANS
1A/div.
IL
1A/div.
MP6001-TPC02
MP6001-TPC01
MP6001-TPC03
Short Circuit Test
Duty Cycle vs Line Voltage
Over current hiccup at VIN = 48V,
IOUT = 4.4A
MAXIMUM DUTY CYCLE (%)
70
60
VOUT
AC Coupled
50mV/div.
50
VSW
100V/div.
VCC
2V/div.
40
30
20
VOUT
2V/div.
ILOAD
1A/div.
IL
1A/div.
1.0
1.5
2.0
2.5
LINE VOLTAGE (V)
100ms/div.
3.0
MP6001-TPC06
MP6001-TPC05
MP6001-TPC04
Shut-down through Enable
Start-up through Enable
VIN = 48V, VOUT = 5V, IOUT = 2.7A
Resistive Load
VIN = 48V, VOUT = 5V, IOUT = 2.7
Resistive Load
VOUT
1V/div.
VCC
2V/div.
VCC
2V/div.
VSW
50V/div.
VOUT
1V/div.
ITRANS
1A/div.
VSW
50V/div.
ITRANS
1A/div.
4ms/div.
4ms/div.
MP6001-TPC07
MP6001 Rev. 0.91
4/5/2006
MP6001-TPC08
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MP6001 – MONOLITHIC FLYBACK/FORWARD DC-DC CONVERTER
INITIAL RELEASE – SPECIFICATIONS SUBJECT TO CHANGE
OPERATION
The MP6001 uses programmable fixedfrequency, peak current-mode PWM with a
single-ended primary architecture to regulate
the output voltage. The MP6001 incorporates
features such as protection circuitry and an
integrated high voltage power switch into a
small 8-pin SOIC. This product targets high
performance, cost effective DC-DC converter
applications.
6 VCC
+
6.5V
4.5V
-LINE 2
+
3.0V
1.2V
OVLO
--
REGULATOR
IBIAS
REF
+
STARTUP
UVLO
--
7 VIN
8 SW
THERMAL
MONITOR
COMP 4
ERROR
AMPLIFIER
1.2V
FB 3
+
CONTROL
LOGIC
--
EA
--
+
1 GND
PWM
COMPARATOR
SOFT-START
CURRENT LIMIT
CLOCK
RT 5
-+
1.0V
--
+
CURRENT LIMIT
COMPARATOR
OSC
SLOPE
COMP
LEB
CURRENT SENSE
MP6001_BD01
Figure 1—Functional Block Diagram
MP6001 Rev. 0.91
4/5/2006
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MP6001 – MONOLITHIC FLYBACK/FORWARD DC-DC CONVERTER
INITIAL RELEASE – SPECIFICATIONS SUBJECT TO CHANGE
High Voltage Startup
The MP6001 features a 100V startup circuit,
see Figure 1. When power is applied, the
capacitor at the VCC pin is charged through the
VIN pin. When the voltage at the VCC pin
crosses 6.0V without fault, the controller is
enabled. The VCC pin is then disconnected
from the VIN pin and VCC voltage is discharged
via the operating current. When VCC drops to
4.5V, the VCC pin is reconnected to the VIN pin
and VCC will be recharged. The voltage at the
VCC pin repeats this ramp cycle between 4.5V
and 6.0V. The VCC pin can be powered with a
voltage higher than 4.5V from an auxiliary
winding to reduce the power dissipated in the
internal startup circuit. The VCC pin is internally
clamped at 8V.
Under-Voltage and Over-Voltage Detection
The MP6001 includes a line monitor circuit.
Two external resistors form a voltage divider
from the input voltage to GND; its tap connects
to the LINE pin. The controller is operational
when the voltage at the UV/OV pin is between
1.2V and 3V. When the voltage at the UV/OV
pin goes out of this operating range, the
controller is disabled and goes into standby
mode. The LINE pin can also be used as a
remote enable. Grounding the UV/OV pin will
disable the controller.
Error Amplifier
The MP6001 includes an error amplifier with its
non-inverting input connected to internal 1.2V
reference voltage. The regulated voltage is fed
back through a resistor network or an
optocoupler to the FB pin. Figure 2 shows some
common error amplifier configurations.
6 VCC
D1
1.2V
C1
+
EA
--
R1
FB
COMP
3
4
C2
PRIMARY
WINDING
R3
C3
R2
(a) Using Primary winding to provide feedback
6 VCC
1.2V
+
EA
--
C2
COMP
FB
3
4
R3
R2
(b) Feedback is from Secondary (Common Collector)
6 VCC
1.2V
+
EA
--
C2
COMP
FB
3
4
(c) Feedback is from Secondary (Common Emitter)
MP6001_F02
Figure 2—Error Amplifier Configurations
MP6001 Rev. 0.91
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MP6001 – MONOLITHIC FLYBACK/FORWARD DC-DC CONVERTER
INITIAL RELEASE – SPECIFICATIONS SUBJECT TO CHANGE
Synchronize Programmable Oscillator
The MP6001 oscillating frequency is set by an
external resistor from the RT pin to ground. The
value of RT can be calculated from:
RT = 10kΩ ×
550KHz
fS
The MP6001 can be synchronized to an
external clock pulse. The frequency of the clock
pulse must be higher than the internal oscillator
frequency. The clock pulse width should be
within 50ns to 150ns. The external clock can be
coupled to the RT pin with a 100pF capacitor
and a peak level greater than 3.5V.
Auto-Restart
When VCC is biased from an auxiliary winding
and an open loop condition occurs, the voltage
at the VCC pin increases to 6.5V. When VCC
crosses the threshold voltage, the auto-restart
circuit turns off the power switch and puts the
controller in standby mode. When VCC drops to
4.5V, the startup switch turns on to charge VCC
up again. When VCC crosses 6.0V, the switch
turns off and the standby current discharges
VCC back to 4.5V. After repeating the ramp
cycles between the two threshold voltages 15
times, the auto-restart circuit is disabled and the
controller begins soft-start.
Duty Cycle Limiting with Line Feed Forward
The MP6001 has a DMAX (maximum duty cycle)
limit at 67.5% when the LINE pin voltage is
equal to 1.3V. As VLINE increases, DMAX
reduces. Maximum duty cycle can be calculated
by:
⎡
⎤
2 .7 V
D MAX = ⎢
⎥ × 100%
⎣ 2.7 V + VLINE ⎦
Limiting the duty cycle at high line voltage
protects against magnetic saturation and
minimizes the output sensitivity to line
transients.
MP6001 Rev. 0.91
4/5/2006
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MP6001 – MONOLITHIC FLYBACK/FORWARD DC-DC CONVERTER
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APPLICATION INFORMATION
Switching Frequency
The frequency (fS), has big effects on the
selection of the transformer (Tr), the output cap,
(C2), and the input cap, (C1). The higher the
frequency, the smaller the sizes for Tr, C2, and
C1. However, a higher frequency also leads to
higher AC power losses in the power switch,
control circuitry, transformer, and in the external
interconnection. The general rule states that
lower the output power, higher the optimum
switching frequency. For low current (<10A)
applications, fS is usually 200KHz to 300KHz if
synchronous rectifiers are used and 300KHz to
500KHz if Schottky rectifiers are used.
Fundamental Equations
The transformer turns ratio N is defined as:
N=
NP
NS
Where NP and NS are the number of turns of the
primary and secondary side windings,
respectively.
The output voltage VO is estimated to be:
VO =
V
D
× IN
1− D
N
The steady-state drain to source voltage of the
primary power switch when it is off is estimated
as:
VDS = VIN + N × VO
VD2 = VO +
For a 5V power supply design, with
VIN=36V~75V, below table shows the voltage
stresses of the power switch (S) and the
rectifier (D2).
Table 1—Main Switch (S) and Rectifier (D2)
Voltage Stress vs. Transformer Turns Ratio
Where D is the duty cycle.
The steady-state reverse voltage
Schottky diode D2 is estimated as:
Transformer (Coupled Inductor) Design
1. Transformer Turns Ratio
The transformer turns ratio determines the duty
cycle range, selection of the rectifier (D2),
primary side peak current, primary snubber
loss, and the current as well as voltage stresses
on the power switch (S). It also has effects on
the selection of C1 and C2. A higher
transformer turns ratio (N) means the following:
• Higher Duty Cycle
• Higher voltage stress on S (VDS), but
lower voltage stress on D2 (VD2).
• Lower primary side RMS current
(IS(RMS)), but higher secondary side RMS
current (ID2(RMS)).
• Use of a smaller input capacitor but
bigger output capacitor.
• Lower primary side peak current
(IS(PEAK)) and lower primary snubber loss.
• Lower main switch (S) turn-on loss
of
the
VIN
N
The output current is calculated as:
IO = ID × (1 − D)
N
DMAX
4
5
6
7
8
9
10
11
0.36
0.41
0.45
0.49
0.53
0.56
0.58
0.60
VDS
(V)
119
125
131
138
144
150
156
163
VDS/0.9
(V)
132
139
146
153
160
167
174
181
VD2
(V)
38
32
28
25
23
21
20
19
VD2/0.9
(V)
42
36
31
28
26
24
22
21
Note:
The voltage spike due to the leakage inductance of the
transformer and device’s voltage rating/derating factors were
considered. See power switch selection and snubber design for
more information.
Where ID is the average current through
Schottky diode when it is conducting.
The input current is calculated as:
IIN = IS × D
Where IS is the average current through the
primary power switch when it is conducting.
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MP6001 – MONOLITHIC FLYBACK/FORWARD DC-DC CONVERTER
INITIAL RELEASE – SPECIFICATIONS SUBJECT TO CHANGE
2. Ripple Factor of the Magnetizing Current
The conduction loss in S, D2, the transformer,
the snubber, and in the ESR of the input/output
capacitors will increase as the ripple of the
magnetizing current increases. The ripple factor
(Kr) is defined as the ratio of the peak-to-peak
ripple current vs. the average current as shown
in Figure 3.
∆I
Kr = M
IM
Where IM can be derived either from input or
output current;
I
I0
IM = IN =
D N × (1 − D)
Solid wire, Litz wire, PCB winding, Flex PCB
winding or any combination thereof can be used
as transformer winding. For low current
applications, solid wire is the most cost effective
choice. Consider using several wires in parallel
and interleaving the winding structure for better
performance of the transformer.
The number of primary turns can be determined
by:
NP =
Where BMAX is the allowed maximum flux
density (usually below 300mT) and AE is the
effective area of the core.
The air gap can be estimated by:
ID2/N
IM
Gap =
IM
0
DTS
TS
MP6001_F03
Figure 3—Magnetic Current of Flyback
Transformer (Reflected to Primary Side)
The input/output ripple voltage will also
increase with a high ripple factor, which makes
the filter bigger and more expensive. On the
other hand, it can help to minimize the turn-on
loss of S and reverse-recovery loss due to D2.
With nominal input voltage, Kr can be selected
at 60%~120% for most DC-DC converters.
The primary side (or magnetizing) inductance
can be determined by:
LF =
L F × IP
B MAX × A E
VIN × D × TS
K r × IM
µ o × N2 × A E
LF
5. Right Half Plane Zero
A Flyback converter operating in continuous
mode has a right half plane (RHP) zero. In the
frequency domain, this RHP zero adds not only
a phase lag to the control characteristics but
also increases the gain of the circuit. Typical
rule of thumb states that the highest usable
loop crossover frequency is limited to one third
the value of the RHP zero. The expression for
the location of the RHP zero in a continuous
mode flyback is given by:
fRHPZ = R LOAD ×
(1 − D) 2
× N2
2π × L F × D
Where RLOAD is the load resistance, LF is the
magnetizing inductance on transformer primary
side, and N is the transformer’s turn ratio.
Reducing the primary inductance increases the
RHP zero frequency which results in higher
crossover frequencies.
3. Core Selection
Pick a core based on experience or through a
catalog (Refer to http://www.ferroxcube.com).
Select an ER, EQ, PQ, or RM core to minimize
the transformer’s leakage inductance.
4. Winding Selection
MP6001 Rev. 0.91
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MP6001 – MONOLITHIC FLYBACK/FORWARD DC-DC CONVERTER
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Duty Cycle Range
The duty cycle range is determined once N is
selected. In general, the optimum operating
duty cycle should be smaller for high input/low
output than low input/high output applications.
Except for high output voltage or wide input
range applications, the maximum D usually
does not exceed 60%.
Voltage Stress of the Internal Power Switch
& External Schottky Diode
For the internal power switch, the voltage stress
is given by:
VDS = VIN + VO × N + VP
Where VP is a function of LLK (leakage
inductrance), fS, R, C, CDS, VIN, IO, etc. Please
refer to Figure 4. The lower the LLK and Io, the
lower the Vp. Smaller R can reduce Vp, but
power loss will increase. See Snubber Design
for details.
Typically VP can be selected as 20~40% of
(VIN+NVO).
LLK
VC
-- C
+
R
D2
Tr
C2
can be selected
(VO+VIN/N), thus:
VPD2
as
40~100%
of
VDS(MAX) = K s × ( VIN(MAX) + NV0 )
Where KS=1.2~1.4, and
VD 2(MAX ) = K D 2 ⋅ ( V0 +
VIN(MAX )
N
)
Where KD2=1.4~2.
For example,
VIN(MAX ) = 75 V, N = 8, K S = 1.25, K D2 = 1.6, VO = 5 V
So
VDS = 1.25 × (75 V + 8 × 5 V ) = 144 V
VD2 = 1.6 × (5 V + 75 V ÷ 8) = 23 V
the power switch rating should be higher than
144V, and the rated voltage for the
synchronous rectifier or Schottky diode should
be higher than 23V.
Snubber Design (Passive)
Snubber for Power Switch
Figure 5 shows four different ways to clamp the
voltage on the power device. RCD type of
snubber circuit is widely used in many
applications.
D
C1
ID2
IS
+
VDS
--
S
S
RD
S
DZ
CD
(A)
(B)
VP
VC
VDS
CD
VIN
RD
DZ
S
S
0
MP6001_F04
(C)
(D)
MP6001_F05
Figure 4—Key Operation Waveform
For the rectifier, D2, the voltage stress is given
by:
VD2 = VO +
Figure 5—Snubber Designs
VIN
+ VPD 2
N
Use of a R-C or R-C-D type snubber circuit for
D2 is recommended.
MP6001 Rev. 0.91
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MP6001 – MONOLITHIC FLYBACK/FORWARD DC-DC CONVERTER
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RCD Type of Snubber Design Procedure:
1. Setting VP
Higher VP means higher voltage stress on the
power switch, but lower power loss. Usually, VP
can be set as 20%~40% of (VIN+ NxVO).
VP
VC
N x VO
VIN
For a given AC ripple voltage, ∆VIN_PP, C1 can
be derived from:
C1 =
IIN × (1 − D) × TS
∆VIN _ PP
∆VIN_PP may affect the C1 voltage rating and
converter stability. C1 RMS current has to be
considered:
(1 − D)
D
IRMS _ C1 = IIN ×
C1 has to have enough RMS current rating.
VDS
0
MP6001_F06
Figure 6—Voltage Waveform of Primary
Power Switch Shown in Figure 5(C)
2. Estimated RCD snubber loss is given by:
PRCD _ LOSS = PLK × (1 +
N × VO
)
VP
Where:
PLK =
1
2
L LK × IP × f C
2
PLK is the energy stored in the leakage
inductance (LLK), which carries the peak current
at the power switch turn-off.
3. Calculate values of the RD and CD of RCD
snubber by:
RD =
VP
2
PRCD _ LOSS
R D × CD
1
>>
fS
Input Capacitor
The input capacitors (C1) are chosen based
upon the AC voltage ripple on the input
capacitors, RMS current ratings, and voltage
rating of the input capacitors.
MP6001 Rev. 0.91
4/5/2006
Output Filter
The simplest filter is an output capacitor (C2),
whose capacitance is determined by the output
ripple requirement.
The current waveform in the output capacitor is
mostly in rectangular shape. The full load
current is drawn from the capacitors during the
primary switch on time. The worse case for the
output ripple occurs under low line and full load
conditions. The ripple voltage can be estimated
by:
∆V0 −PP −C = IO ×
D
C2 × f S
ESR also needs to be specified for the output
capacitors. This is due to the step change in D2
current results in a ripple voltage that is
proportional to the ESR. Assuming that the D2
current waveform is in rectangular shape, the
ESR requirement is then obtained by given the
output ripple voltage.
∆VO −PP _ RESR =
IO × ESR
(1 − D)
The total ripple voltage can be estimated by:
∆VO −PP = ∆VO −PP −C + ∆VO −PP _ ESR
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© 2006 MPS. All Rights Reserved.
11
TM
MP6001 – MONOLITHIC FLYBACK/FORWARD DC-DC CONVERTER
INITIAL RELEASE – SPECIFICATIONS SUBJECT TO CHANGE
Control Design
Generally, telecom power supplies require the
galvanic isolation between a relatively high
input voltage and low output voltages. The most
widely used devices to transfer signals across
the isolation boundary are pulse transformers
and optocouplers.
VO
D
Tr
VIN
RESR
CO
+
--
RLOAD
The MP6001 uses current mode control to
achieve easy compensation and fast transient
response. A type II compensation network
which has two poles and one zero is needed to
stabilize
the
system.
The
practical
compensation parameters are provided in the
EV6001DN datasheet.
Boost Controller Application
The MP6001 can be used as a boost controller
as shown in Figure 8.
D1
200V/1A
VIN
d
S
VCC
1
R5
R1
+
2
GND
SW
LINE
VIN
8
7
MP6001
R6
--
180V
20mA
R2 C1
R3
--
3
+
4
VREF
R4
TL431
FB
VCC
COMP
RT
6
5
Rb
C3
10nF
MP6001_F07
Figure 7—Simplified Circuit of Isolated
Power Supply with Optocoupler Feedback
MP6001 _F08
Figure 8—High Voltage LED Boost
Controller Circuit
MP6001 Rev. 0.91
4/5/2006
www.MonolithicPower.com
MPS Proprietary Information. Unauthorized Photocopy and Duplication Prohibited.
© 2006 MPS. All Rights Reserved.
12
TM
MP6001 – MONOLITHIC FLYBACK/FORWARD DC-DC CONVERTER
INITIAL RELEASE – SPECIFICATIONS SUBJECT TO CHANGE
PACKAGE INFORMATION
SOIC8N
PIN 1 IDENT.
0.229(5.820)
0.244(6.200)
0.0075(0.191)
0.0098(0.249)
0.150(3.810)
0.157(4.000)
SEE DETAIL "A"
NOTE 2
0.011(0.280) x 45o
0.020(0.508)
0.013(0.330)
0.020(0.508)
0.050(1.270)BSC
0.189(4.800)
0.197(5.004)
0.053(1.350)
0.068(1.730)
0o-8o
0.049(1.250)
0.060(1.524)
0.016(0.410)
0.050(1.270)
DETAIL "A"
SEATING PLANE
0.001(0.030)
0.004(0.101)
NOTE:
1) Control dimension is in inches. Dimension in bracket is millimeters.
2) Exposed Pad Option Only (N-Package) ; 2.55+/- 0.25mm x 3.38 +/- 0.44mm.
Recommended Solder Board Area: 2.80mm x 3.82mm = 10.7mm2 (16.6mil2)
NOTICE: The information in this document is subject to change without notice. Please contact MPS for current specifications.
Users should warrant and guarantee that third party Intellectual Property rights are not infringed upon when integrating MPS
products into any application. MPS will not assume any legal responsibility for any said applications.
MP6001 Rev. 0.91
4/5/2006
www.MonolithicPower.com
MPS Proprietary Information. Unauthorized Photocopy and Duplication Prohibited.
© 2006 MPS. All Rights Reserved.
13