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 LTC1871 Wide Input Range, No RSENSETM Current Mode Boost, Flyback and SEPIC Controller
FEATURES
s s s
DESCRIPTIO
s s s s s
s s s s s
s
High Efficiency (No Sense Resistor Required) Wide Input Voltage Range: 2.5V to 36V Current Mode Control Provides Excellent Transient Response High Maximum Duty Cycle (92% Typ) 2% RUN Pin Threshold with 100mV Hysteresis 1% Internal Voltage Reference Micropower Shutdown: IQ = 10A Programmable Operating Frequency (50kHz to 1MHz) with One External Resistor Synchronizable to an External Clock Up to 1.3 x fOSC User-Controlled Pulse Skip or Burst Mode(R) Operation Internal 5.2V Low Dropout Voltage Regulator Output Overvoltage Protection Capable of Operating with a Sense Resistor for High Output Voltage Applications Small 10-Lead MSOP Package
The LTC(R)1871 is a wide input range, current mode, boost, flyback and SEPIC controller that drives an N-channel power MOSFET and requires very few external components. Intended for low to medium power applications, it eliminates the need for a current sense resistor by utilizing the power MOSFET's on-resistance, thereby maximizing efficiency. The IC's operating frequency can be set with an external resistor over a 50kHz to 1MHz range, and can be synchronized to an external clock using the MODE/SYNC pin. Burst Mode operation at light loads, a low minimum operating supply voltage of 2.5V and a low shutdown quiescent current of 10A make the LTC1871 ideally suited for battery-operated systems. For applications requiring constant frequency operation, Burst Mode operation can be defeated using the MODE/ SYNC pin. Higher output voltage boost, SEPIC and flyback applications are possible with the LTC1871 by connecting the SENSE pin to a resistor in the source of the power MOSFET. The LTC1871 is available in the 10-lead MSOP package.
, LTC and LT are registered trademarks of Linear Technology Corporation. Burst Mode is a registered trademark of Linear Technology Corporation. No RSENSE is a trademark of Linear Technology Corporation.
APPLICATIO S
s s
Telecom Power Supplies Portable Electronic Equipment
TYPICAL APPLICATIO
VIN 3.3V L1 1H D1 90 RUN ITH RC 22k CC1 6.8nF CC2 47pF R2 37.4k 1% R1 12.1k 1% FB FREQ RT 80.6k 1% MODE/SYNC LTC1871 INTVCC GATE GND CVCC 4.7F X5R SENSE VIN VOUT 5V 7A (10A PEAK) COUT2 22F 6.3V X5R x2 GND 80 EFFICIENCY (%) 70 60 50 40 30 0.001 100
+
M1
COUT1 150F 6.3V x4
+
CIN 22F 6.3V x2
1871 F01a
CIN: TAIYO YUDEN JMK325BJ226MM COUT1: PANASONIC EEFUEOJ151R COUT2: TAIYO YUDEN JMK325BJ226MM
D1: MBRB2515L L1: SUMIDA CEP125-H 1R0MH M1: FAIRCHILD FDS7760A
Figure 1. High Efficiency 3.3V Input, 5V Output Boost Converter (Bootstrapped)
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Efficiency of Figure 1
Burst Mode OPERATION PULSE-SKIP MODE 0.01 0.1 1 OUTPUT CURRENT (A) 10
1871 F01b
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U
1
LTC1871
ABSOLUTE
(Note 1)
AXI U
RATI GS
PACKAGE/ORDER I FOR ATIO
ORDER PART NUMBER
TOP VIEW RUN ITH FB FREQ MODE/ SYNC 1 2 3 4 5 10 9 8 7 6 SENSE VIN INTVCC GATE GND
VIN Voltage ............................................... - 0.3V to 36V INTVCC Voltage ........................................... - 0.3V to 7V INTVCC Output Current ........................................ 50mA GATE Voltage ........................... - 0.3V to VINTVCC + 0.3V ITH, FB Voltages ....................................... - 0.3V to 2.7V RUN, MODE/SYNC Voltages ....................... - 0.3V to 7V FREQ Voltage ............................................- 0.3V to 1.5V SENSE Pin Voltage ................................... - 0.3V to 36V Operating Temperature Range (Note 2) .. - 40C to 85C Junction Temperature (Note 3) ............................ 125C Storage Temperature Range ................. - 65C to 150C Lead Temperature (Soldering, 10 sec).................. 300C
LTC1871EMS
MS PACKAGE 10-LEAD PLASTIC MSOP
MS PART MARKING LTSX
TJMAX = 125C, JA = 120C/ W
Consult LTC Marketing for parts specified with wider operating temperature ranges.
ELECTRICAL CHARACTERISTICS
The q denotes specifications which apply over the full operating temperature range, otherwise specifications are at TA = 25C. VIN = VINTVCC = 5V, VRUN = 1.5V, RFREQ = 80k, VMODE/SYNC = 0V, unless otherwise specified.
SYMBOL VIN(MIN) IQ PARAMETER Minimum Input Voltage Input Voltage Supply Current Continuous Mode Burst Mode Operation, No Load Shutdown Mode Rising RUN Input Threshold Voltage Falling RUN Input Threshold Voltage
q
CONDITIONS
MIN 2.5
TYP
MAX
UNITS V
Main Control Loop (Note 4) VMODE/SYNC = 5V, VFB = 1.4V, VITH = 0.75V VMODE/SYNC = 0V, VITH = 0.2V (Note 5) VRUN = 0V 1.223 1.198 50 VITH = 0.2V (Note 5)
q
550 250 10 1.348 1.248 100 1 1.218 1.212 1.230 18 0.002
q
1000 500 20 1.273 1.298 150 60 1.242 1.248 60 0.02
VRUN+ VRUN- VRUN(HYST) IRUN VFB IFB VFB VIN VFB VITH VFB(OV) gm VITH(BURST) ISENSE(ON) ISENSE(OFF)
RUN Pin Input Threshold Hysteresis RUN Input Current Feedback Voltage FB Pin Input Current Line Regulation Load Regulation FB Pin, Overvoltage Lockout Error Amplifier Transconductance Burst Mode Operation ITH Pin Voltage SENSE Pin Current (GATE High) SENSE Pin Current (GATE Low)
VITH = 0.2V (Note 5) 2.5V VIN 30V VMODE/SYNC = 0V, VTH = 0.5V to 0.90V (Note 5) VFB(OV) - VFB(NOM) in Percent ITH Pin Load = 5A (Note 5) Falling ITH Voltage (Note 5) Duty Cycle < 20% VSENSE = 0V VSENSE = 30V 120 -1 2.5
- 0.1 6 650 0.3 150 35 0.1 180 50 5 10
VSENSE(MAX) Maximum Current Sense Input Threshold
2
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A A A V V V mV nA V V nA %/V % % mho V mV A A
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U
WW
W
LTC1871
The q denotes specifications which apply over the full operating temperature range, otherwise specifications are at TA = 25C. VIN = VINTVCC = 5V, VRUN = 1.5V, RFREQ = 80k, VMODE/SYNC = 0V, unless otherwise specified.
SYMBOL Oscillator fOSC DMAX fSYNC/fOSC tSYNC(MIN) tSYNC(MAX) VIL(MODE) VIH(MODE) RMODE/SYNC VFREQ VINTVCC VINTVCC VIN1 VINTVCC VIN2 VLDO(LOAD) VDROPOUT IINTVCC GATE Driver tr tf GATE Driver Output Rise Time GATE Driver Output Fall Time CL = 3300pF (Note 7) CL = 3300pF (Note 7) 17 8 100 100 ns ns Oscillator Frequency Oscillator Frequency Range Maximum Duty Cycle Recommended Maximum Synchronized Frequency Ratio MODE/SYNC Minimum Input Pulse Width MODE/SYNC Maximum Input Pulse Width Low Level MODE/SYNC Input Voltage High Level MODE/SYNC Input Voltage MODE/SYNC Input Pull-Down Resistance Nominal FREQ Pin Voltage INTVCC Regulator Output Voltage INTVCC Regulator Line Regulation INTVCC Regulator Line Regulation INTVCC Load Regulation INTVCC Regulator Dropout Voltage Bootstrap Mode INTVCC Supply Current in Shutdown VIN = 7.5V 7.5V VIN 15V 15V VIN 30V 0 IINTVCC 20mA, VIN = 7.5V VIN = 5V, INTVCC Load = 20mA RUN = 0V, SENSE = 5V -2 5.0 1.2 50 0.62 5.2 8 70 - 0.2 280 10 20 5.4 25 200 fOSC = 300kHz (Note 6) VSYNC = 0V to 5V VSYNC = 0V to 5V RFREQ = 80k 250 50 87 92 1.25 25 0.8/fOSC 0.3 300 350 1000 97 1.30 ns ns V V k V V mV mV % mV A kHz kHz % PARAMETER CONDITIONS MIN TYP MAX UNITS
ELECTRICAL CHARACTERISTICS
Low Dropout Regulator
Note 1: Absolute Maximum Ratings are those values beyond which the life of the device may be impaired. Note 2: The LTC1871E is guaranteed to meet performance specifications from 0C to 70C. Specifications over the - 40C to 85C operating temperature range are assured by design, characterization and correlation with statistical process controls. Note 3: TJ is calculated from the ambient temperature TA and power dissipation PD according to the following formula: TJ = TA + (PD * 120C/W)
Note 4: The dynamic input supply current is higher due to power MOSFET gate charging (QG * fOSC). See Applications Information. Note 5: The LTC1871 is tested in a feedback loop that servos VFB to the reference voltage with the ITH pin forced to a voltage between 0V and 1.4V (the no load to full load operating voltage range for the ITH pin is 0.3V to 1.23V). Note 6: In a synchronized application, the internal slope compensation gain is increased by 25%. Synchronizing to a significantly higher ratio will reduce the effective amount of slope compensation, which could result in subharmonic oscillation for duty cycles greater than 50%. Note 7: Rise and fall times are measured at 10% and 90% levels.
3
LTC1871 TYPICAL PERFOR A CE CHARACTERISTICS
FB Voltage vs Temp
1.25
FB PIN CURRENT (nA) 0 5 10 15 20 VIN (V) 25 30 35
1.24
FB VOLTAGE (V)
FB VOLTAGE (V)
1.23
1.22
1.21 -50 -25
0
25 50 75 100 125 150 TEMPERATURE (C)
1871 G01
Shutdown Mode IQ vs VIN
30
SHUTDOWN MODE IQ (A)
SHUTDOWN MODE IQ (A)
20
Burst Mode IQ (A)
10
0 0 10 20 VIN (V)
30
Burst Mode IQ vs Temperature
500 18 16 400 14 12
Burst Mode IQ (A)
TIME (ns)
IQ (mA)
300
200
100
0 -50 -25
0
25 50 75 100 125 150 TEMPERATURE (C)
1871 G07
4
UW
1871 G04
FB Voltage Line Regulation
1.231 60 50 40 30 20 10 1.229
FB Pin Current vs Temperature
1.230
0 -50 -25
0
25 50 75 100 125 150 TEMPERATURE (C)
1871 G03
1871 G02
Shutdown Mode IQ vs Temperature
20 VIN = 5V
600 500
Burst Mode IQ vs VIN
15
400 300 200 100
10
5
40
0 -50 -25
0
25 50 75 100 125 150 TEMPERATURE (C)
1871 G05
0
0
10
20 VIN (V)
30
40
1871 G06
Dynamic IQ vs Frequency
CL = 3300pF IQ(TOT) = 550A + Qg * f
Gate Drive Rise and Fall Time vs CL
60 50 40 RISE TIME 30 20 FALL TIME 10
10 8 6 4 2 0 0 200 400 600 800 FREQUENCY (kHz) 1000 1200
0
0
2000
4000
6000 8000 CL (pF)
10000 12000
1871 G09
1871 G08
LTC1871 TYPICAL PERFOR A CE CHARACTERISTICS
RUN Thresholds vs VIN
1.5
1.40
RUN THRESHOLDS (V)
1.4
RUN THRESHOLDS (V)
RT (k) 0 25 50 75 100 125 150 TEMPERATURE (C)
1871 G11
1.3
1.2 0 10 20 VIN (V)
30
Frequency vs Temperature
325 320
160
GATE FREQUENCY (kHz)
155
310 305 300 295 290 285 280 275 -50 -25 0 25 50 75 100 125 150 TEMPERATURE (C)
1871 G13
150
SENSE PIN CURRENT (A)
315
MAX SENSE THRESHOLD (mV)
INTVCC Load Regulation
5.4
VIN = 7.5V
DROPOUT VOLTAGE (mV)
5.2
INTVCC VOLTAGE (V)
INTVCC VOLTAGE (V)
5.1
5.0 0 10 20 30 40 50 60 INTVCC LOAD (mA) 70 80
UW
1871 G10
1871 G16
RUN Thresholds vs Temperature
1000
RT vs Frequency
1.35
1.30
100
1.25
40
1.20 -50 -25
10
0 100 200 300 400 500 600 700 800 900 1000 FREQUENCY (kHz)
1871 G12
Maximum Sense Threshold vs Temperature
35
SENSE Pin Current vs Temperature
GATE HIGH VSENSE = 0V
30
145
140 -50 -25
0
25 50 75 100 125 150 TEMPERATURE (C)
1871 G14
25 -50 -25
0
25 50 75 100 125 150 TEMPERATURE (C)
1871 G15
INTVCC Line Regulation
500 450
INTVCC Dropout Voltage vs Current, Temperature
150C 400 350 300 250 200 150 100 50 25C 125C 75C
5.3
5.2
0C -50C
5.1 0 5 10 15
20 25 VIN (V)
30
0
35
40
0
5
10 15 INTVCC LOAD (mA)
20
1871 G18
1871 G17
5
LTC1871
PI FU CTIO S
RUN (Pin 1): The RUN pin provides the user with an accurate means for sensing the input voltage and programming the start-up threshold for the converter. The falling RUN pin threshold is nominally 1.248V and the comparator has 100mV of hysteresis for noise immunity. When the RUN pin is below this input threshold, the IC is shut down and the VIN supply current is kept to a low value (typ 10A). The Absolute Maximum Rating for the voltage on this pin is 7V. ITH (Pin 2): Error Amplifier Compensation Pin. The current comparator input threshold increases with this control voltage. Nominal voltage range for this pin is 0V to 1.40V. FB (Pin 3): Receives the feedback voltage from the external resistor divider across the output. Nominal voltage for this pin in regulaton is 1.230V. FREQ (Pin 4): A resistor from the FREQ pin to ground programs the operating frequency of the chip. The nominal voltage at the FREQ pin is 0.6V. MODE/SYNC (Pin 5): This input controls the operating mode of the converter and allows for synchronizing the operating frequency to an external clock. If the MODE/ SYNC pin is connected to ground, Burst Mode operation is enabled. If the MODE/SYNC pin is connected to INTVCC, or if an external logic-level synchronization signal is applied to this input, Burst Mode operation is disabled and the IC operates in a continuous mode. GND (Pin 6): Ground Pin. GATE (Pin 7): Gate Driver Output. INTVCC (Pin 8): The Internal 5.20V Regulator Output. The gate driver and control circuits are powered from this voltage. Decouple this pin locally to the IC ground with a minimum of 4.7F low ESR tantalum or ceramic capacitor. VIN (Pin 9): Main Supply Pin. Must be closely decoupled to ground. SENSE (Pin 10): The Current Sense Input for the Control Loop. Connect this pin to the drain of the power MOSFET for VDS sensing and highest efficiency. Alternatively, the SENSE pin may be connected to a resistor in the source of the power MOSFET. Internal leading edge blanking is provided for both sensing methods.
6
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LTC1871
BLOCK DIAGRA
FREQ 4 0.6V MODE/SYNC 5 85mV 1.230V 50k OV IOSC PWM LATCH LOGIC S Q R BURST COMPARATOR CURRENT COMPARATOR C1 GND INTVCC V-TO-I OSC
0.30V FB 3 EA gm 1.230V ITH 2 INTVCC 8 5.2V
LDO
1.230V SLOPE 1.230V
UV TO START-UP CONTROL GND BIAS VREF 6
1871 BD
2.00V
+
-
+
+
+
-
+
-
-
W
RUN SLOPE COMPENSATION BIAS AND START-UP CONTROL
+
C2
1
-
1.248V VIN 9
GATE 7
SENSE
+ -
10
V-TO-I ILOOP RLOOP
VIN
7
LTC1871
OPERATIO
Main Control Loop The LTC1871 is a constant frequency, current mode controller for DC/DC boost, SEPIC and flyback converter applications. The LTC1871 is distinguished from conventional current mode controllers because the current control loop can be closed by sensing the voltage drop across the power MOSFET switch instead of across a discrete sense resistor, as shown in Figure 2. This sensing technique improves efficiency, increases power density, and reduces the cost of the overall solution.
L VIN VIN SENSE VSW GATE GND GND D VOUT
2a. SENSE Pin Connection for Maximum Efficiency (VSW < 36V)
L VIN VIN GATE VSW D VOUT
GND
2b. SENSE Pin Connection for Precise Control of Peak Current or for VSW > 36V Figure 2. Using the SENSE Pin On the LTC1871
For circuit operation, please refer to the Block Diagram of the IC and Figure 1. In normal operation, the power MOSFET is turned on when the oscillator sets the PWM latch and is turned off when the current comparator C1 resets the latch. The divided-down output voltage is compared to an internal 1.230V reference by the error amplifier EA, which outputs an error signal at the ITH pin. The voltage on the ITH pin sets the current comparator C1 input threshold. When the load current increases, a fall in the FB voltage relative to the reference voltage causes the ITH pin
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to rise, which causes the current comparator C1 to trip at a higher peak inductor current value. The average inductor current will therefore rise until it equals the load current, thereby maintaining output regulation. The nominal operating frequency of the LTC1871 is programmed using a resistor from the FREQ pin to ground and can be controlled over a 50kHz to 1000kHz range. In addition, the internal oscillator can be synchronized to an external clock applied to the MODE/SYNC pin and can be locked to a frequency between 100% and 130% of its nominal value. When the MODE/SYNC pin is left open, it is pulled low by an internal 50k resistor and Burst Mode operation is enabled. If this pin is taken above 2V or an external clock is applied, Burst Mode operation is disabled and the IC operates in continuous mode. With no load (or an extremely light load), the controller will skip pulses in order to maintain regulation and prevent excessive output ripple. The RUN pin controls whether the IC is enabled or is in a low current shutdown state. A micropower 1.248V reference and comparator C2 allow the user to program the supply voltage at which the IC turns on and off (comparator C2 has 100mV of hysteresis for noise immunity). With the RUN pin below 1.248V, the chip is off and the input supply current is typically only 10A. An overvoltage comparator OV senses when the FB pin exceeds the reference voltage by 6.5% and provides a reset pulse to the main RS latch. Because this RS latch is reset-dominant, the power MOSFET is actively held off for the duration of an output overvoltage condition. The LTC1871 can be used either by sensing the voltage drop across the power MOSFET or by connecting the SENSE pin to a conventional shunt resistor in the source of the power MOSFET, as shown in Figure 2. Sensing the voltage across the power MOSFET maximizes converter efficiency and minimizes the component count, but limits the output voltage to the maximum rating for this pin (36V). By connecting the SENSE pin to a resistor in the source of the power MOSFET, the user is able to program output voltages significantly greater than 36V.
+
COUT
+
SENSE GND COUT RS
1871 F02
LTC1871
OPERATIO
Programming the Operating Mode For applications where maximizing the efficiency at very light loads (e.g., <100A) is a high priority, the current in the output divider could be decreased to a few microamps and Burst Mode operation should be applied (i.e., the MODE/SYNC pin should be connected to ground). In applications where fixed frequency operation is more critical than low current efficiency, or where the lowest output ripple is desired, pulse-skip mode operation should be used and the MODE/SYNC pin should be connected to the INTVCC pin. This allows discontinuous conduction mode (DCM) operation down to near the limit defined by the chip's minimum on-time (about 175ns). Below this output current level, the converter will begin to skip cycles in order to maintain output regulation. Figures 3 and 4 show the light load switching waveforms for Burst Mode and pulse-skip mode operation for the converter in Figure 1. Burst Mode Operation Burst Mode operation is selected by leaving the MODE/ SYNC pin unconnected or by connecting it to ground. In normal operation, the range on the ITH pin corresponding to no load to full load is 0.30V to 1.2V. In Burst Mode operation, if the error amplifier EA drives the ITH voltage below 0.525V, the buffered ITH input to the current comparator C1 will be clamped at 0.525V (which corresponds to 25% of maximum load current). The inductor current peak is then held at approximately 30mV divided by the
VIN = 3.3V VOUT = 5V IOUT = 500mA VOUT 50mV/DIV MODE/SYNC = 0V (Burst Mode OPERATION)
IL 5A/DIV
Figure 3. LTC1871 Burst Mode Operation (MODE/SYNC = 0V) at Low Output Current
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power MOSFET RDS(ON). If the ITH pin drops below 0.30V, the Burst Mode comparator B1 will turn off the power MOSFET and scale back the quiescent current of the IC to 250A (sleep mode). In this condition, the load current will be supplied by the output capacitor until the ITH voltage rises above the 50mV hysteresis of the burst comparator. At light loads, short bursts of switching (where the average inductor current is 20% of its maximum value) followed by long periods of sleep will be observed, thereby greatly improving converter efficiency. Oscilloscope waveforms illustrating Burst Mode operation are shown in Figure 3. Pulse-Skip Mode Operation With the MODE/SYNC pin tied to a DC voltage above 2V, Burst Mode operation is disabled. The internal, 0.525V buffered ITH burst clamp is removed, allowing the ITH pin to directly control the current comparator from no load to full load. With no load, the ITH pin is driven below 0.30V, the power MOSFET is turned off and sleep mode is invoked. Oscilloscope waveforms illustrating this mode of operation are shown in Figure 4. When an external clock signal drives the MODE/SYNC pin at a rate faster than the chip's internal oscillator, the oscillator will synchronize to it. In this synchronized mode, Burst Mode operation is disabled. The constant frequency associated with synchronized operation provides a more controlled noise spectrum from the converter, at the expense of overall system efficiency of light loads.
VIN = 3.3V VOUT = 5V IOUT = 500mA VOUT 50mV/DIV MODE/SYNC = INTVCC (PULSE-SKIP MODE) IL 5A/DIV 10s/DIV
1871 F03
2s/DIV
1871 F04
Figure 4. LTC1871 Low Output Current Operation with Burst Mode Operation Disabled (MODE/SYNC = INTVCC)
9
LTC1871
APPLICATIO S I FOR ATIO
When the oscillator's internal logic circuitry detects a synchronizing signal on the MODE/SYNC pin, the internal oscillator ramp is terminated early and the slope compensation is increased by approximately 30%. As a result, in applications requiring synchronization, it is recommended that the nominal operating frequency of the IC be programmed to be about 75% of the external clock frequency. Attempting to synchronize to too high an external frequency (above 1.3fO) can result in inadequate slope compensation and possible subharmonic oscillation (or jitter). The external clock signal must exceed 2V for at least 25ns, and should have a maximum duty cycle of 80%, as shown in Figure 5. The MOSFET turn on will synchronize to the rising edge of the external clock signal.
2V TO 7V MODE/ SYNC tMIN = 25ns 0.8T T T = 1/fO
RT (k)
GATE
D = 40%
IL
1871 F05
Figure 5. MODE/SYNC Clock Input and Switching Waveforms for Synchronized Operation
Programming the Operating Frequency The choice of operating frequency and inductor value is a tradeoff between efficiency and component size. Low frequency operation improves efficiency by reducing MOSFET and diode switching losses. However, lower frequency operation requires more inductance for a given amount of load current. The LTC1871 uses a constant frequency architecture that can be programmed over a 50kHz to 1000kHz range with a single external resistor from the FREQ pin to ground, as shown in Figure 1. The nominal voltage on the FREQ pin is 0.6V, and the current that flows into the FREQ pin is used
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to charge and discharge an internal oscillator capacitor. A graph for selecting the value of RT for a given operating frequency is shown in Figure 6.
1000 100 10 0 100 200 300 400 500 600 700 800 900 1000 FREQUENCY (kHz)
1871 F06
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Figure 6. Timing Resistor (RT) Value
INTVCC Regulator Bypassing and Operation An internal, P-channel low dropout voltage regulator produces the 5.2V supply which powers the gate driver and logic circuitry within the LTC1871, as shown in Figure 7. The INTVCC regulator can supply up to 50mA and must be bypassed to ground immediately adjacent to the IC pins with a minimum of 4.7F tantalum or ceramic capacitor. Good bypassing is necessary to supply the high transient currents required by the MOSFET gate driver. For input voltages that don't exceed 7V (the absolute maximum rating for this pin), the internal low dropout regulator in the LTC1871 is redundant and the INTVCC pin can be shorted directly to the VIN pin. With the INTVCC pin shorted to VIN, however, the divider that programs the regulated INTVCC voltage will draw 10A of current from the input supply, even in shutdown mode. For applications that require the lowest shutdown mode input supply current, do not connect the INTVCC pin to VIN. Regardless of whether the INTVCC pin is shorted to VIN or not, it is always necessary to have the driver circuitry bypassed with a 4.7F tantalum or low ESR ceramic capacitor to ground immediately adjacent to the INTVCC and GND pins. In an actual application, most of the IC supply current is used to drive the gate capacitance of the power MOSFET.
LTC1871
APPLICATIO S I FOR ATIO
1.230V
R2
R1
LOGIC
Figure 7. Bypassing the LDO Regulator and Gate Driver Supply
As a result, high input voltage applications in which a large power MOSFET is being driven at high frequencies can cause the LTC1871 to exceed its maximum junction temperature rating. The junction temperature can be estimated using the following equations: IQ(TOT) IQ + f * QG PIC = VIN * (IQ + f * QG) TJ = TA + PIC * RTH(JA) The total quiescent current IQ(TOT) consists of the static supply current (IQ) and the current required to charge and discharge the gate of the power MOSFET. The 10-pin MSOP package has a thermal resistance of RTH(JA) = 120C/W. As an example, consider a power supply with VIN = 5V and VO = 12V at IO = 1A. The switching frequency is 500kHz, and the maximum ambient temperature is 70C. The power MOSFET chosen is the IRF7805, which has a maximum RDS(ON) of 11m (at room temperature) and a maximum total gate charge of 37nC (the temperature coefficient of the gate charge is low). IQ(TOT) = 600A + 37nC * 500kHz = 19.1mA PIC = 5V * 19.1mA = 95mW TJ = 70C + 120C/W * 95mW = 81.4C
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VIN INPUT SUPPLY 2.5V TO 30V P-CH CIN 5.2V INTVCC
W
+
-
UU
+
DRIVER GATE
CVCC 4.7F M1
GND
1871 F07
GND PLACE AS CLOSE AS POSSIBLE TO DEVICE PINS
This demonstrates how significant the gate charge current can be when compared to the static quiescent current in the IC. To prevent the maximum junction temperature from being exceeded, the input supply current must be checked when operating in a continuous mode at high VIN. A tradeoff between the operating frequency and the size of the power MOSFET may need to be made in order to maintain a reliable IC junction temperature. Prior to lowering the operating frequency, however, be sure to check with power MOSFET manufacturers for their latest-and-greatest low QG, low RDS(ON) devices. Power MOSFET manufacturing technologies are continually improving, with newer and better performance devices being introduced almost yearly. Output Voltage Programming The output voltage is set by a resistor divider according to the following formula: R2 VO = 1.230 V * 1 + R1 The external resistor divider is connected to the output as shown in Figure 1, allowing remote voltage sensing. The resistors R1 and R2 are typically chosen so that the error
11
LTC1871
APPLICATIO S I FOR ATIO
caused by the current flowing into the FB pin during normal operation is less than 1% (this translates to a maximum value of R1 of about 250k). Programming Turn-On and Turn-Off Thresholds with the RUN Pin The LTC1871 contains an independent, micropower voltage reference and comparator detection circuit that remains active even when the device is shut down, as shown in Figure 8. This allows users to accurately program an input voltage at which the converter will turn on and off. The falling threshold voltage on the RUN pin is equal to the internal reference voltage of 1.248V. The comparator has 100mV of hysteresis to increase noise immunity.
+
R2
INPUT SUPPLY
OPTIONAL FILTER CAPACITOR
R1 1.248V POWER REFERENCE GND
1871 F8a
-
Figure 8a. Programming the Turn-On and Turn-Off Thresholds Using the RUN Pin
RUN COMPARATOR RUN 6V EXTERNAL LOGIC CONTROL 1.248V
+ -
1871 F08b
Figure 8b. On/Off Control Using External Logic
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The turn-on and turn-off input voltage thresholds are programmed using a resistor divider according to the following formulas:
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R2 VIN(OFF) = 1.248 V * 1 + R1 R2 VIN(ON) = 1.348 V * 1 + R1
The resistor R1 is typically chosen to be less than 1M. For applications where the RUN pin is only to be used as a logic input, the user should be aware of the 7V Absolute Maximum Rating for this pin! The RUN pin can be connected to the input voltage through an external 1M resistor, as shown in Figure 8c, for "always on" operaton.
VIN RUN COMPARATOR BIAS AND START-UP CONTROL
RUN 6V
+ -
+
R2 1M INPUT SUPPLY
VIN RUN COMPARATOR
RUN 6V
+ -
-
GND
1.248V
1871 F08c
Figure 8c. External Pull-Up Resistor On RUN Pin for "Always On" Operation
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Application Circuits
A basic LTC1871 application circuit is shown in Figure 1. External component selection is driven by the characteristics of the load and the input supply. The first topology to be analyzed will be the boost converter, followed by SEPIC (single ended primary inductance converter). Boost Converter: Duty Cycle Considerations For a boost converter operating in a continuous conduction mode (CCM), the duty cycle of the main switch is:
V +V -V D = O D IN VO + VD
where VD is the forward voltage of the boost diode. For converters where the input voltage is close to the output voltage, the duty cycle is low and for converters that develop a high output voltage from a low voltage input supply, the duty cycle is high. The maximum output voltage for a boost converter operating in CCM is:
VO(MAX) =
VIN(MIN) -V (1- DMAX ) D
The maximum duty cycle capability of the LTC1871 is typically 92%. This allows the user to obtain high output voltages from low input supply voltages. Boost Converter: The Peak and Average Input Currents The control circuit in the LTC1871 is measuring the input current (either by using the RDS(ON) of the power MOSFET or by using a sense resistor in the MOSFET source), so the output current needs to be reflected back to the input in order to dimension the power MOSFET properly. Based on the fact that, ideally, the output power is equal to the input power, the maximum average input current is:
IO(MAX) IIN(MAX) = 1 - DMAX The peak input current is: IO(MAX) IIN(PEAK) = 1 + * 2 1 - DMAX
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The maximum duty cycle, DMAX, should be calculated at minimum VIN. Boost Converter: Ripple Current IL and the `' Factor The constant `' in the equation above represents the percentage peak-to-peak ripple current in the inductor, relative to its maximum value. For example, if 30% ripple current is chosen, then = 0.30, and the peak current is 15% greater than the average. For a current mode boost regulator operating in CCM, slope compensation must be added for duty cycles above 50% in order to avoid subharmonic oscillation. For the LTC1871, this ramp compensation is internal. Having an internally fixed ramp compensation waveform, however, does place some constraints on the value of the inductor and the operating frequency. If too large an inductor is used, the resulting current ramp (IL) will be small relative to the internal ramp compensation (at duty cycles above 50%), and the converter operation will approach voltage mode (ramp compensation reduces the gain of the current loop). If too small an inductor is used, but the converter is still operating in CCM (near critical conduction mode), the internal ramp compensation may be inadequate to prevent subharmonic oscillation. To ensure good current mode gain and avoid subharmonic oscillation, it is recommended that the ripple current in the inductor fall in the range of 20% to 40% of the maximum average current. For example, if the maximum average input current is 1A, choose a IL between 0.2A and 0.4A, and a value `' between 0.2 and 0.4. Boost Converter: Inductor Selection Given an operating input voltage range, and having chosen the operating frequency and ripple current in the inductor, the inductor value can be determined using the following equation:
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L= where:
VIN(MIN) * DMAX IL * f IO(MAX) 1 - DMAX
IL = *
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Remember that boost converters are not short-circuit protected. Under a shorted output condition, the inductor current is limited only by the input supply capability. For applications requiring a step-up converter that is shortcircuit protected, please refer to the applications section covering SEPIC converters. The minimum required saturation current of the inductor can be expressed as a function of the duty cycle and the load current, as follows: IO(MAX) IL(SAT) 1 + * 2 1 - DMAX The saturation current rating for the inductor should be checked at the minimum input voltage (which results in the highest inductor current) and maximum output current. Boost Converter: Operating in Discontinuous Mode Discontinuous mode operation occurs when the load current is low enough to allow the inductor current to run out during the off-time of the switch, as shown in Figure 9. Once the inductor current is near zero, the switch and diode capacitances resonate with the inductance to form damped ringing at 1MHz to 10MHz. If the off-time is long enough, the drain voltage will settle to the input voltage. Depending on the input voltage and the residual energy in the inductor, this ringing can cause the drain of the power MOSFET to go below ground where it is clamped by the body diode. This ringing is not harmful to the IC and it has not been shown to contribute significantly to EMI. Any attempt to damp it with a snubber will degrade the efficiency.
VIN = 3.3V IOUT = 200mA VOUT = 5V MOSFET DRAIN VOLTAGE 2V/DIV
INDUCTOR CURRENT 2A/DIV
2s/DIV
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Figure 9. Discontinuous Mode Waveforms
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Boost Converter: Inductor Core Selection Once the value for L is known, the type of inductor must be selected. High efficiency converters generally cannot afford the core loss found in low cost powdered iron cores, forcing the use of more expensive ferrite, molypermalloy or Kool M(R) cores. Actual core loss is independent of core size for a fixed inductor value, but is very dependent on the inductance selected. As inductance increases, core losses go down. Unfortunately, increased inductance requires more turns of wire and therefore, copper losses will increase. Generally, there is a tradeoff between core losses and copper losses that needs to be balanced. Ferrite designs have very low core losses and are preferred at high switching frequencies, so design goals can concentrate on copper losses and preventing saturation. Ferrite core material saturates "hard," meaning that the inductance collapses rapidly when the peak design current is exceeded. This results in an abrupt increase in inductor ripple current and consequently, output voltage ripple. Do not allow the core to saturate! Molypermalloy (from Magnetics, Inc.) is a very good, low cost core material for toroids, but is more expensive than ferrite. A reasonable compromise from the same manufacturer is Kool M. Boost Converter: Power MOSFET Selection The power MOSFET serves two purposes in the LTC1871: it represents the main switching element in the power path, and its RDS(ON) represents the current sensing element for the control loop. Important parameters for the power MOSFET include the drain-to-source breakdown voltage (BVDSS), the threshold voltage (VGS(TH)), the onresistance (RDS(ON)) versus gate-to-source voltage, the gate-to-source and gate-to-drain charges (QGS and QGD, respectively), the maximum drain current (ID(MAX)) and the MOSFET's thermal resistances (RTH(JC) and RTH(JA)). The gate drive voltage is set by the 5.2V INTVCC low drop regulator. Consequently, logic-level threshold MOSFETs should be used in most LTC1871 applications. If low input voltage operation is expected (e.g., supplying power from
Kool M is a registered trademark of Magnetics, Inc.
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a lithium-ion battery or a 3.3V logic supply), then sublogiclevel threshold MOSFETs should be used. Pay close attention to the BVDSS specifications for the MOSFETs relative to the maximum actual switch voltage in the application. Many logic-level devices are limited to 30V or less, and the switch node can ring during the turn-off of the MOSFET due to layout parasitics. Check the switching waveforms of the MOSFET directly across the drain and source terminals using the actual PC board layout (not just on a lab breadboard!) for excessive ringing. During the switch on-time, the control circuit limits the maximum voltage drop across the power MOSFET to about 150mV (at low duty cycle). The peak inductor current is therefore limited to 150mV/RDS(ON). The relationship between the maximum load current, duty cycle and the RDS(ON) of the power MOSFET is: RDS(ON) VSENSE(MAX) * 1 - DMAX 1 + * IO(MAX) * T 2
The VSENSE(MAX) term is typically 150mV at low duty cycle, and is reduced to about 100mV at a duty cycle of 92% due to slope compensation, as shown in Figure 10. The T term accounts for the temperature coefficient of the RDS(ON) of the MOSFET, which is typically 0.4%/C. Figure 11 illustrates the variation of normalized RDS(ON) over temperature for a typical power MOSFET.
200
MAXIMUM CURRENT SENSE VOLTAGE (mV)
T NORMALIZED ON RESISTANCE
150
100
50
0
0
0.2
0.5 0.4 DUTY CYCLE
0.8
1.0
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Figure 10. Maximum SENSE Threshold Voltage vs Duty Cycle
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Another method of choosing which power MOSFET to use is to check what the maximum output current is for a given RDS(ON), since MOSFET on-resistances are available in discrete values. IO(MAX) = VSENSE(MAX) * 1 - DMAX 1 + * RDS(ON) * T 2 It is worth noting that the 1 - DMAX relationship between IO(MAX) and RDS(ON) can cause boost converters with a wide input range to experience a dramatic range of maximum input and output current. This should be taken into consideration in applications where it is important to limit the maximum current drawn from the input supply. Calculating Power MOSFET Switching and Conduction Losses and Junction Temperatures In order to calculate the junction temperature of the power MOSFET, the power dissipated by the device must be known. This power dissipation is a function of the duty cycle, the load current and the junction temperature itself (due to the positive temperature coefficient of its RDS(ON)). As a result, some iterative calculation is normally required to determine a reasonably accurate value. Since the controller is using the MOSFET as both a switching and a sensing element, care should be taken to ensure that the converter is capable of delivering the required load current over all operating conditions (line voltage and temperature), and for the worst-case specifications for VSENSE(MAX)
2.0 1.5 1.0 0.5 0 - 50 50 100 0 JUNCTION TEMPERATURE (C) 150
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Figure 11. Normalized RDS(ON) vs Temperature
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and the RDS(ON) of the MOSFET listed in the manufacturer's data sheet. The power dissipated by the MOSFET in a boost converter is:
IO(MAX) PFET = * RDS(ON) * DMAX * T 1 - DMAX IO(MAX) + k * VO1.85 * *C *f (1- DMAX ) RSS
The first term in the equation above represents the I2R losses in the device, and the second term, the switching losses. The constant, k = 1.7, is an empirical factor inversely related to the gate drive current and has the dimension of 1/current. From a known power dissipated in the power MOSFET, its junction temperature can be obtained using the following formula: TJ = TA + PFET * RTH(JA) The RTH(JA) to be used in this equation normally includes the RTH(JC) for the device plus the thermal resistance from the case to the ambient temperature (RTH(CA)). This value of TJ can then be compared to the original, assumed value used in the iterative calculation process. Boost Converter: Output Diode Selection To maximize efficiency, a fast switching diode with low forward drop and low reverse leakage is desired. The output diode in a boost converter conducts current during the switch off-time. The peak reverse voltage that the diode must withstand is equal to the regulator output voltage. The average forward current in normal operation is equal to the output current, and the peak current is equal to the peak inductor current. IO(MAX) ID(PEAK) = IL(PEAK) = 1 + * 2 1 - DMAX The power dissipated by the diode is: PD = IO(MAX) * VD
2
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and the diode junction temperature is: TJ = TA + PD * RTH(JA) The RTH(JA) to be used in this equation normally includes the RTH(JC) for the device plus the thermal resistance from the board to the ambient temperature in the enclosure. Remember to keep the diode lead lengths short and to observe proper switch-node layout (see Board Layout Checklist) to avoid excessive ringing and increased dissipation. Boost Converter: Output Capacitor Selection Contributions of ESR (equivalent series resistance), ESL (equivalent series inductance) and the bulk capacitance must be considered when choosing the correct component for a given output ripple voltage. The effects of these three parameters (ESR, ESL and bulk C) on the output voltage ripple waveform are illustrated in Figure 12e for a typical boost converter. The choice of component(s) begins with the maximum acceptable ripple voltage (expressed as a percentage of the output voltage), and how this ripple should be divided between the ESR step and the charging/discharging V. For the purpose of simplicity we will choose 2% for the maximum output ripple, to be divided equally between the ESR step and the charging/discharging V. This percentage ripple will change, depending on the requirements of the application, and the equations provided below can easily be modified. For a 1% contribution to the total ripple voltage, the ESR of the output capacitor can be determined using the following equation:
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ESRCOUT
where:
0.01 * VO IIN(PEAK)
IO(MAX) IIN(PEAK)= 1 + * 2 1 - DMAX
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For the bulk C component, which also contributes 1% to the total ripple: COUT IO(MAX) 0.01 * VO * f
For many designs it is possible to choose a single capacitor type that satisfies both the ESR and bulk C requirements for the design. In certain demanding applications, however, the ripple voltage can be improved significantly by connecting two or more types of capacitors in parallel. For example, using a low ESR ceramic capacitor can minimize the ESR step, while an electrolytic capacitor can be used to supply the required bulk C. Once the output capacitor ESR and bulk capacitance have been determined, the overall ripple voltage waveform should be verified on a dedicated PC board (see Board Layout section for more information on component placement). Lab breadboards generally suffer from excessive series inductance (due to inter-component wiring), and these parasitics can make the switching waveforms look significantly worse than they would be on a properly designed PC board. The output capacitor in a boost regulator experiences high RMS ripple currents, as shown in Figure 12. The RMS output capacitor ripple current is:
IRMS(COUT) IO(MAX) * VO - VIN(MIN) VIN(MIN)
Note that the ripple current ratings from capacitor manufacturers are often based on only 2000 hours of life. This makes it advisable to further derate the capacitor or to choose a capacitor rated at a higher temperature than required. Several capacitors may also be placed in parallel to meet size or height requirements in the design. Manufacturers such as Nichicon, United Chemicon and Sanyo should be considered for high performance throughhole capacitors. The OS-CON semiconductor dielectric capacitor available from Sanyo has the lowest product of ESR and size of any aluminum electrolytic, at a somewhat higher price.
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In surface mount applications, multiple capacitors may have to be placed in parallel in order to meet the ESR or RMS current handling requirements of the application. Aluminum electrolytic and dry tantalum capacitors are both available in surface mount packages. In the case of tantalum, it is critical that the capacitors have been surge tested for use in switching power supplies. An excellent choice is AVX TPS series of surface mount tantalum. Also, ceramic capacitors are now available with extremely low ESR, ESL and high ripple current ratings. Boost Converter: Input Capacitor Selection The input capacitor of a boost converter is less critical than the output capacitor, due to the fact that the inductor is in series with the input and the input current waveform is
L D VOUT VIN SW COUT RL
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12a. Circuit Diagram
IL IIN
12b. Inductor and Input Currents
ISW tON
12c. Switch Current
ID
tOFF
IO
12d. Diode and Output Currents
VCOUT VOUT (AC) VESR RINGING DUE TO TOTAL INDUCTANCE (BOARD + CAP)
12e. Output Voltage Ripple Waveform
Figure 12. Switching Waveforms for a Boost Converter
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VENDOR AVX BH Electronics Coilcraft Coiltronics Diodes, Inc Fairchild General Semiconductor International Rectifier IRC Kemet Magnetics Inc Microsemi Murata-Erie Nichicon On Semiconductor Panasonic Sanyo Sumida Taiyo Yuden TDK Thermalloy Tokin Toko United Chemicon Vishay/Dale Vishay/Siliconix Vishay/Sprague Zetex
Table 1. Recommended Component Manufacturers
COMPONENTS Capacitors Inductors, Transformers Inductors Inductors Diodes MOSFETs Diodes MOSFETs, Diodes Sense Resistors Tantalum Capacitors Toroid Cores Diodes Inductors, Capacitors Capacitors Diodes Capacitors Capacitors Inductors Capacitors Capacitors, Inductors Heat Sinks Capacitors Inductors Capacitors Resistors MOSFETs Capacitors Small-Signal Discretes TELEPHONE (207) 282-5111 (952) 894-9590 (847) 639-6400 (407) 241-7876 (805) 446-4800 (408) 822-2126 (516) 847-3000 (310) 322-3331 (361) 992-7900 (408) 986-0424 (800) 245-3984 (617) 926-0404 (770) 436-1300 (847) 843-7500 (602) 244-6600 (714) 373-7334 (619) 661-6835 (847) 956-0667 (408) 573-4150 (562) 596-1212 (972) 243-4321 (408) 432-8020 (847) 699-3430 (847) 696-2000 (605) 665-9301 (800) 554-5565 (207) 324-4140 (631) 543-7100 WEB ADDRESS avxcorp.com bhelectronics.com coilcraft.com coiltronics.com diodes.com fairchildsemi.com generalsemiconductor.com irf.com irctt.com kemet.com mag-inc.com microsemi.com murata.co.jp nichicon.com onsemi.com panasonic.com sanyo.co.jp sumida.com t-yuden.com component.tdk.com aavidthermalloy.com tokin.com tokoam.com chemi-com.com vishay.com vishay.com vishay.com zetex.com
continuous (see Figure 12b). The input voltage source impedance determines the size of the input capacitor, which is typically in the range of 10F to 100F. A low ESR capacitor is recommended, although it is not as critical as for the output capacitor. The RMS input capacitor ripple current for a boost converter is:
VIN(MIN) * DMAX L*f Please note that the input capacitor can see a very high surge current when a battery is suddenly connected to the input of the converter and solid tantalum capacitors can fail catastrophically under these conditions. Be sure to specify surge-tested capacitors! IRMS(CIN) = 0.3 *
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Burst Mode Operation and Considerations The choice of MOSFET RDS(ON) and inductor value also determines the load current at which the LTC1871 enters Burst Mode operation. When bursting, the controller clamps the peak inductor current to approximately:
IBURST(PEAK) = 30mV RDS(ON)
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which represents about 20% of the maximum 150mV SENSE pin voltage. The corresponding average current depends upon the amount of ripple current. Lower inductor values (higher IL) will reduce the load current at which Burst Mode operations begins, since it is the peak current that is being clamped.
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The output voltage ripple can increase during Burst Mode operation if IL is substantially less than IBURST. This can occur if the input voltage is very low or if a very large inductor is chosen. At high duty cycles, a skipped cycle causes the inductor current to quickly decay to zero. However, because IL is small, it takes multiple cycles for the current to ramp back up to IBURST(PEAK). During this inductor charging interval, the output capacitor must supply the load current and a significant droop in the output voltage can occur. Generally, it is a good idea to choose a value of inductor IL between 25% and 40% of IIN(MAX). The alternative is to either increase the value of the output capacitor or disable Burst Mode operation using the MODE/SYNC pin. Burst Mode operation can be defeated by connecting the MODE/SYNC pin to a high logic-level voltage (either with a control input or by connecting this pin to INTVCC). In this mode, the burst clamp is removed, and the chip can operate at constant frequency from continuous conduction mode (CCM) at full load, down into deep discontinuous conduction mode (DCM) at light load. Prior to skipping pulses at very light load (i.e., < 5% of full load), the controller will operate with a minimum switch on-time in DCM. Pulse skipping prevents a loss of control of the output at very light loads and reduces output voltage ripple. Efficiency Considerations: How Much Does VDS Sensing Help? The efficiency of a switching regulator is equal to the output power divided by the input power (x100%). Percent efficiency can be expressed as: % Efficiency = 100% - (L1 + L2 + L3 + ...), where L1, L2, etc. are the individual loss components as a percentage of the input power. It is often useful to analyze individual losses to determine what is limiting the efficiency and which change would produce the most improvement. Although all dissipative elements in the circuit produce losses, four main sources usually account for the majority of the losses in LTC1871 application circuits:
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1. The supply current into VIN. The VIN current is the sum of the DC supply current IQ (given in the Electrical Characteristics) and the MOSFET driver and control currents. The DC supply current into the VIN pin is typically about 550A and represents a small power loss (much less than 1%) that increases with VIN. The driver current results from switching the gate capacitance of the power MOSFET; this current is typically much larger than the DC current. Each time the MOSFET is switched on and then off, a packet of gate charge QG is transferred from INTVCC to ground. The resulting dQ/dt is a current that must be supplied to the INTVCC capacitor through the VIN pin by an external supply. If the IC is operating in CCM: IQ(TOT) IQ = f * QG PIC = VIN * (IQ + f * QG) 2. Power MOSFET switching and conduction losses. The technique of using the voltage drop across the power MOSFET to close the current feedback loop was chosen because of the increased efficiency that results from not having a sense resistor. The losses in the power MOSFET are equal to:
IO(MAX) PFET = * RDS(ON) * DMAX * T 1 - DMAX IO(MAX) * CRSS * f + k * VO1.85 * 1 - DMAX
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The I2R power savings that result from not having a discrete sense resistor can be calculated almost by inspection.
IO(MAX) PR(SENSE) = * RSENSE * DMAX 1 - DMAX
To understand the magnitude of the improvement with this VDS sensing technique, consider the 3.3V input, 5V output power supply shown in Figure 1. The maximum load current is 7A (10A peak) and the duty cycle is 39%. Assuming a ripple current of 40%, the peak inductor current is 13.8A and the average is 11.5A. With a maximum sense voltage of about 140mV, the sense
2
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resistor value would be 10m, and the power dissipated in this resistor would be 514mW at maximum output current. Assuming an efficiency of 90%, this sense resistor power dissipation represents 1.3% of the overall input power. In other words, for this application, the use of VDS sensing would increase the efficiency by approximately 1.3%. For more details regarding the various terms in these equations, please refer to the section Boost Converter: Power MOSFET Selection. 3. The losses in the inductor are simply the DC input current squared times the winding resistance. Expressing this loss as a function of the output current yields:
IO(MAX) PR(WINDING) = * RW 1 - DMAX
2
4. Losses in the boost diode. The power dissipation in the boost diode is: PDIODE = IO(MAX) * VD The boost diode can be a major source of power loss in a boost converter. For the 3.3V input, 5V output at 7A example given above, a Schottky diode with a 0.4V forward voltage would dissipate 2.8W, which represents 7% of the input power. Diode losses can become significant at low output voltages where the forward voltage is a significant percentage of the output voltage. 5. Other losses, including CIN and CO ESR dissipation and inductor core losses, generally account for less than 2% of the total additional loss. Checking Transient Response The regulator loop response can be verified by looking at the load transient response. Switching regulators generally take several cycles to respond to an instantaneous step in resistive load current. When the load step occurs, VO immediately shifts by an amount equal to (ILOAD)(ESR), and then CO begins to charge or discharge (depending on the direction of the load step) as shown in Figure 13. The regulator feedback loop acts on the resulting error amp output signal to return VO to its steady-state value. During this recovery time, VO can be monitored for overshoot or ringing that would indicate a stability problem.
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IOUT 2A/DIV VIN = 3.3V VOUT = 5V MODE/SYNC = INTVCC (PULSE-SKIP MODE) VOUT (AC) 100mV/DIV 100s/DIV
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Figure 13. Load Transient Response for a 3.3V Input, 5V Output Boost Converter Application, 0.7A to 7A Step
A second, more severe transient can occur when connecting loads with large (> 1F) supply bypass capacitors. The discharged bypass capacitors are effectively put in parallel with CO, causing a nearly instantaneous drop in VO. No regulator can deliver enough current to prevent this problem if the load switch resistance is low and it is driven quickly. The only solution is to limit the rise time of the switch drive in order to limit the inrush current di/dt to the load. Boost Converter Design Example The design example given here will be for the circuit shown in Figure 1. The input voltage is 3.3V, and the output is 5V at a maximum load current of 7A (10A peak). 1. The duty cycle is:
V + V - V 5 + 0.4 - 3.3 D = O D IN = = 38.9% VO + VD 5 + 0.4
2. Pulse-skip operation is chosen so the MODE/SYNC pin is shorted to INTVCC. 3. The operating frequency is chosen to be 300kHz to reduce the size of the inductor. From Figure 5, the resistor from the FREQ pin to ground is 80k. 4. An inductor ripple current of 40% of the maximum load current is chosen, so the peak input current (which is also the minimum saturation current) is:
7 IO(MAX) IIN(PEAK) = 1 + * = 1.2 * = 13.8 A 2 1 - DMAX 1 - 0. 39
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The inductor ripple current is:
IL = * IO(MAX) 7 = 0.4 * = 4.6 A 1 - DMAX 1 - 0.39
And so the inductor value is:
L= VIN(MIN) 3.3V * DMAX = * 0.39 = 0.93H IL * f 4.6 A * 300kHz
The component chosen is a 1H inductor made by Sumida (part number CEP125-H 1ROMH) which has a saturation current of greater than 20A. 5. With the input voltage to the IC bootstrapped to the output of the power supply (5V), a logic-level MOSFET can be used. Because the duty cycle is 39%, the maximum SENSE pin threshold voltage is reduced from its low duty cycle typical value of 150mV to approximately 140mV. Assuming a MOSFET junction temperature of 125C, the room temperature MOSFET RDS(ON) should be less than:
RDS(ON) VSENSE(MAX) *
1 - DMAX 1 + * IO(MAX) * T 2 1 - 0.39 = 0.140 V * = 6.8m 0.4 1+ * 7 A * 1.5 2
The MOSFET used was the Fairchild FDS7760A, which has a maximum RDS(ON) of 8m at 4.5V VGS, a BVDSS of greater than 30V, and a gate charge of 37nC at 5V VGS. 6. The diode for this design must handle a maximum DC output current of 10A and be rated for a minimum reverse voltage of VOUT, or 5V. A 25A, 15V diode from On Semiconductor (MBRB2515L) was chosen for its high power dissipation capability. 7. The output capacitor usually consists of a high valued bulk C connected in parallel with a lower valued, low ESR ceramic. Based on a maximum output ripple voltage of 1%, or 50mV, the bulk C needs to be greater than:
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COUT IOUT(MAX) = 0.01 * VOUT * f 7A = 466F 0.01 * 5V * 300kHz
The RMS ripple current rating for this capacitor needs to exceed:
IRMS(COUT) IO(MAX) * 7A * 5V - 3.3V = 5A 3.3V VO - VIN(MIN) = VIN(MIN)
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To satisfy this high RMS current demand, four 150F Panasonic capacitors (EEFUEOJ151R) are required. In parallel with these bulk capacitors, two 22F, low ESR (X5R) Taiyo Yuden ceramic capacitors (JMK325BJ226MM) are added for HF noise reduction. Check the output ripple with a single oscilloscope probe connected directly across the output capacitor terminals, where the HF switching currents flow. 8. The choice of an input capacitor for a boost converter depends on the impedance of the source supply and the amount of input ripple the converter will safely tolerate. For this particular design and lab setup a 100F Sanyo Poscap (6TPC 100M), in parallel with two 22F Taiyo Yuden ceramic capacitors (JMK325BJ226MM) is required (the input and return lead lengths are kept to a few inches, but the peak input current is close to 20A!). As with the output node, check the input ripple with a single oscilloscope probe connected across the input capacitor terminals. PC Board Layout Checklist 1. In order to minimize switching noise and improve output load regulation, the GND pin of the LTC1871 should be connected directly to 1) the negative terminal of the INTVCC decoupling capacitor, 2) the negative terminal of the output decoupling capacitors, 3) the source of the power MOSFET or the bottom terminal of the sense resistor, 4) the negative terminal of the input capacitor and 5) at least one via to the ground plane
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immediately adjacent to Pin 6. The ground trace on the top layer of the PC board should be as wide and short as possible to minimize series resistance and inductance.
JUMPER R3 RC R2 R1 RT CC R4 J1 PIN 1 LTC1871 CIN
CVCC
PSEUDO-KELVIN SIGNAL GROUND CONNECTION
COUT
VIAS TO GROUND PLANE TRUE REMOTE OUTPUT SENSING
BULK C
Figure 14. LTC1871 Boost Converter Suggested Layout
R3 R4 CC 1 RC 2 10 9 J1 SWITCH NODE L1 SENSE VIN
RUN ITH LTC1871
R1 R2 RT
3 4 5
FB FREQ MODE/ SYNC
BOLD LINES INDICATE HIGH CURRENT PATHS
Figure 15. LTC1871 Boost Converter Layout Diagram
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2. Beware of ground loops in multiple layer PC boards. Try to maintain one central ground node on the board and use the input capacitor to avoid excess input ripple for high output current power supplies. If the ground plane
VIN L1 M1 SWITCH NODE IS ALSO THE HEAT SPREADER FOR L1, M1, D1 COUT D1 VOUT LOW ESR CERAMIC
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VIN
INTVCC GATE GND
8 7 6 CVCC M1
D1
+
CIN GND COUT VOUT
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LTC1871
APPLICATIO S I FOR ATIO
is to be used for high DC currents, choose a path away from the small-signal components. 3. Place the CVCC capacitor immediately adjacent to the INTVCC and GND pins on the IC package. This capacitor carries high di/dt MOSFET gate drive currents. A low ESR and ESL 4.7F ceramic capacitor works well here. 4. The high di/dt loop from the bottom terminal of the output capacitor, through the power MOSFET, through the boost diode and back through the output capacitors should be kept as tight as possible to reduce inductive ringing. Excess inductance can cause increased stress on the power MOSFET and increase HF noise on the output. If low ESR ceramic capacitors are used on the output to reduce output noise, place these capacitors close to the boost diode in order to keep the series inductance to a minimum. 5. Check the stress on the power MOSFET by measuring its drain-to-source voltage directly across the device terminals (reference the ground of a single scope probe directly to the source pad on the PC board). Beware of inductive ringing which can exceed the maximum specified voltage rating of the MOSFET. If this ringing cannot be avoided and exceeds the maximum rating of the device, either choose a higher voltage device or specify an avalanche-rated power MOSFET. Not all MOSFETs are created equal (some are more equal than others). 6. Place the small-signal components away from high frequency switching nodes. In the layout shown in Figure 14, all of the small-signal components have been placed on one side of the IC and all of the power components have been placed on the other. This also allows the use of a pseudo-Kelvin connection for the signal ground, where high di/dt gate driver currents flow out of the IC ground pin in one direction (to the bottom plate of the INTVCC decoupling capacitor) and small-signal currents flow in the other direction. 7. If a sense resistor is used in the source of the power MOSFET, minimize the capacitance between the SENSE pin trace and any high frequency switching nodes. The LTC1871 contains an internal leading edge blanking time of approximately 180ns, which should be adequate for most applications.
VIN
SW
16a. SEPIC Topology
VIN
VIN
16b. Current Flow During Switch On-Time
VIN D1
VIN
16c. Current Flow During Switch Off-Time
Figures 16. SEPIC Topolgy and Current Flow
+
+
*
+
+
*
+
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8. For optimum load regulation and true remote sensing, the top of the output resistor divider should connect independently to the top of the output capacitor (Kelvin connection), staying away from any high dV/dt traces. Place the divider resistors near the LTC1871 in order to keep the high impedance FB node short. 9. For applications with multiple switching power converters connected to the same input supply, make sure that the input filter capacitor for the LTC1871 is not shared with other converters. AC input current from another converter could cause substantial input voltage ripple, and this could interfere with the operation of the LTC1871. A few inches of PC trace or wire (L 100nH) between the CIN of the LTC1871 and the actual source VIN should be sufficient to prevent current sharing problems. SEPIC Converter Applications The LTC1871 is also well suited to SEPIC (single-ended primary inductance converter) converter applications. The SEPIC converter shown in Figure 16 uses two inductors. The advantage of the SEPIC converter is the input voltage may be higher or lower than the output voltage, and the output is short-circuit protected.
L1 C1 D1
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*
VOUT
+
L2 COUT
RL
*
VOUT
+
*
RL
VOUT
+
*
RL
23
LTC1871
APPLICATIO S I FOR ATIO
The first inductor, L1, together with the main switch, resembles a boost converter. The second inductor, L2, together with the output diode D1, resembles a flyback or buck-boost converter. The two inductors L1 and L2 can be independent but can also be wound on the same core since identical voltages are applied to L1 and L2 throughout the switching cycle. By making L1 = L2 and winding them on the same core the input ripple is reduced along with cost and size. All of the SEPIC applications information that follows assumes L1 = L2 = L.
IL1
IIN SW ON SW OFF
17a. Input Inductor Current
IL2 IO
17b. Output Inductor Current
IIN IC1 IO
17c. DC Coupling Capacitor Current
ID1 IO
17d. Diode Current
VOUT (AC) VCOUT VESR RINGING DUE TO TOTAL INDUCTANCE (BOARD + CAP)
17e. Output Ripple Voltage Figures 17. SEPIC Converter Switching Waveforms
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SEPIC Converter: Duty Cycle Considerations For a SEPIC converter operating in a continuous conduction mode (CCM), the duty cycle of the main switch is:
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VO + VD D= VIN + VO + VD
where VD is the forward voltage of the diode. For converters where the input voltage is close to the output voltage the duty cycle is near 50%. The maximum output voltage for a SEPIC converter is:
VO(MAX) = ( VIN + VD ) DMAX 1 - VD 1 - DMAX 1 - DMAX
The maximum duty cycle of the LTC1871 is typically 92%. SEPIC Converter: The Peak and Average Input Currents The control circuit in the LTC1871 is measuring the input current (either using the RDS(ON) of the power MOSFET or by means of a sense resistor in the MOSFET source), so the output current needs to be reflected back to the input in order to dimension the power MOSFET properly. Based on the fact that, ideally, the output power is equal to the input power, the maximum input current for a SEPIC converter is:
IIN(MAX) = IO(MAX) * The peak input current is: D IIN(PEAK) = 1 + * IO(MAX) * MAX 1 - DMAX 2 DMAX 1 - DMAX
The maximum duty cycle, DMAX, should be calculated at minimum VIN. The constant `' represents the fraction of ripple current in the inductor relative to its maximum value. For example, if 30% ripple current is chosen, then = 0.30 and the peak current is 15% greater than the average.
LTC1871
APPLICATIO S I FOR ATIO
It is worth noting here that SEPIC converters that operate at high duty cycles (i.e., that develop a high output voltage from a low input voltage) can have very high input currents, relative to the output current. Be sure to check that the maximum load current will not overload the input supply. SEPIC Converter: Inductor Selection For most SEPIC applications the equal inductor values will fall in the range of 10H to 100H. Higher values will reduce the input ripple voltage and reduce the core loss. Lower inductor values are chosen to reduce physical size and improve transient response. Like the boost converter, the input current of the SEPIC converter is calculated at full load current and minimum input voltage. The peak inductor current can be significantly higher than the output current, especially with smaller inductors and lighter loads. The following formulas assume CCM operation and calculate the maximum peak inductor currents at minimum VIN: V +V IL1(PEAK) = 1 + * IO(MAX) * O D VIN(MIN) 2 VIN(MIN) + VD IL2(PEAK) = 1 + * IO(MAX) * VIN(MIN) 2 The ripple current in the inductor is typically 20% to 40% (i.e., a range of `' from 0.20 to 0.40) of the maximum average input current occurring at VIN(MIN) and IO(MAX) and IL1 = IL2. Expressing this ripple current as a function of the output current results in the following equations for calculating the inductor value: L= VIN(MIN) * DMAX IL * f
where: IL = * IO(MAX) * DMAX 1 - DMAX
By making L1 = L2 and winding them on the same core, the value of inductance in the equation above is replace by 2L
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due to mutual inductance. Doing this maintains the same ripple current and energy storage in the inductors. For example, a Coiltronix CTX10-4 is a 10H inductor with two windings. With the windings in parallel, 10H inductance is obtained with a current rating of 4A (the number of turns hasn't changed, but the wire diameter has doubled). Splitting the two windings creates two 10H inductors with a current rating of 2A each. Therefore, substituting 2L yields the following equation for coupled inductors: L1 = L2 = VIN(MIN) * DMAX 2 * IL * f Specify the maximum inductor current to safely handle IL(PK) specified in the equation above. The saturation current rating for the inductor should be checked at the minimum input voltage (which results in the highest inductor current) and maximum output current. SEPIC Converter: Power MOSFET Selection The power MOSFET serves two purposes in the LTC1871: it represents the main switching element in the power path, and its RDS(ON) represents the current sensing element for the control loop. Important parameters for the power MOSFET include the drain-to-source breakdown voltage (BVDSS), the threshold voltage (VGS(TH)), the onresistance (RDS(ON)) versus gate-to-source voltage, the gate-to-source and gate-to-drain charges (QGS and QGD, respectively), the maximum drain current (ID(MAX)) and the MOSFET's thermal resistances (RTH(JC) and RTH(JA)). The gate drive voltage is set by the 5.2V INTVCC low dropout regulator. Consequently, logic-level threshold MOSFETs should be used in most LTC1871 applications. If low input voltage operation is expected (e.g., supplying power from a lithium-ion battery), then sublogic-level threshold MOSFETs should be used. The maximum voltage that the MOSFET switch must sustain during the off-time in a SEPIC converter is equal to the sum of the input and output voltages (VO + VIN). As a result, careful attention must be paid to the BVDSS specifications for the MOSFETs relative to the maximum actual switch voltage in the application. Many logic-level devices are limited to 30V or less. Check the switching waveforms directly across the drain and source terminals of the power
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25
LTC1871
APPLICATIO S I FOR ATIO
MOSFET to ensure the VDS remains below the maximum rating for the device. During the MOSFET's on-time, the control circuit limits the maximum voltage drop across the power MOSFET to about 150mV (at low duty cycle). The peak inductor current is therefore limited to 150mV/RDS(ON). The relationship between the maximum load current, duty cycle and the RDS(ON) of the power MOSFET is:
RDS(ON) VSENSE(MAX) 1 * IO(MAX) 1 + * T 2 * 1 VO + VD V +1 IN(MIN)
The VSENSE(MAX) term is typically 150mV at low duty cycle and is reduced to about 100mV at a duty cycle of 92% due to slope compensation, as shown in Figure 8. The constant `' in the denominator represents the ripple current in the inductors relative to their maximum current. For example, if 30% ripple current is chosen, then = 0.30. The T term accounts for the temperature coefficient of the RDS(ON) of the MOSFET, which is typically 0.4%/C. Figure 9 illustrates the variation of normalized RDS(ON) over temperature for a typical power MOSFET. Another method of choosing which power MOSFET to use is to check what the maximum output current is for a given RDS(ON) since MOSFET on-resistances are available in discrete values.
IO(MAX) VSENSE(MAX) 1 * RDS(ON) 1 + * T 2 * 1 VO + VD V +1 IN(MIN)
Calculating Power MOSFET Switching and Conduction Losses and Junction Temperatures In order to calculate the junction temperature of the power MOSFET, the power dissipated by the device must be known. This power dissipation is a function of the duty cycle, the load current and the junction temperature itself. As a result, some iterative calculation is normally required to determine a reasonably accurate value. Since the controller is using the MOSFET as both a switching and a sensing element, care should be taken to ensure that the converter is capable of delivering the required load current
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over all operating conditions (load, line and temperature) and for the worst-case specifications for VSENSE(MAX) and the RDS(ON) of the MOSFET listed in the manufacturer's data sheet. The power dissipated by the MOSFET in a SEPIC converter is: D PFET = IO(MAX) * MAX * RDS(ON) * DMAX * T 1 - DMAX 1.85 D + k * VIN(MIN) + VO * IO(MAX) * MAX * CRSS * f 1 - DMAX
2
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(
)
The first term in the equation above represents the I2R losses in the device and the second term, the switching losses. The constant k = 1.7 is an empirical factor inversely related to the gate drive current and has the dimension of 1/current. From a known power dissipated in the power MOSFET, its junction temperature can be obtained using the following formula: TJ = TA + PFET *RTH(JA) The RTH(JA) to be used in this equation normally includes the RTH(JC) for the device plus the thermal resistance from the board to the ambient temperature in the enclosure. This value of TJ can then be used to check the original assumption for the junction temperature in the iterative calculation process. SEPIC Converter: Output Diode Selection To maximize efficiency, a fast-switching diode with low forward drop and low reverse leakage is desired. The output diode in a SEPIC converter conducts current during the switch off-time. The peak reverse voltage that the diode must withstand is equal to VIN(MAX) + VO. The average forward current in normal operation is equal to the output current, and the peak current is equal to:
V +V ID(PEAK) = 1 + * IO(MAX) * O D + 1 2 VIN(MIN)
The power dissipated by the diode is: PD = IO(MAX) * VD
LTC1871
APPLICATIO S I FOR ATIO
and the diode junction temperature is: TJ = TA + PD * RTH(JA)
The RTH(JA) to be used in this equation normally includes the RTH(JC) for the device plus the thermal resistance from the board to the ambient temperature in the enclosure. SEPIC Converter: Output Capacitor Selection Because of the improved performance of today's electrolytic, tantalum and ceramic capacitors, engineers need to consider the contributions of ESR (equivalent series resistance), ESL (equivalent series inductance) and the bulk capacitance when choosing the correct component for a given output ripple voltage. The effects of these three parameters (ESR, ESL, and bulk C) on the output voltage ripple waveform are illustrated in Figure 17 for a typical coupled-inductor SEPIC converter. The choice of component(s) begins with the maximum acceptable ripple voltage (expressed as a percentage of the output voltage), and how this ripple should be divided between the ESR step and the charging/discharging V. For the purpose of simplicity we will choose 2% for the maximum output ripple, to be divided equally between the ESR step and the charging/discharging V. This percentage ripple will change, depending on the requirements of the application, and the equations provided below can easily be modified. For a 1% contribution to the total ripple voltage, the ESR of the output capacitor can be determined using the following equation:
0.01 * VO ESRCOUT ID(PEAK)
where:
V +V ID(PEAK) = 1 + * IO(MAX) * O D + 1 2 VIN(MIN)
For the bulk C component, which also contributes 1% to the total ripple: COUT IO(MAX) 0.01 * VO * f
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For many designs it is possible to choose a single capacitor type that satisfies both the ESR and bulk C requirements for the design. In certain demanding applications, however, the ripple voltage can be improved significantly by connecting two or more types of capacitors in parallel. For example, using a low ESR ceramic capacitor can minimize the ESR step, while an electrolytic or tantalum capacitor can be used to supply the required bulk C. Once the output capacitor ESR and bulk capacitance have been determined, the overall ripple voltage waveform should be verified on a dedicated PC board (see Board Layout section for more information on component placement). Lab breadboards generally suffer from excessive series inductance (due to inter-component wiring), and these parasitics can make the switching waveforms look significantly worse than they would be on a properly designed PC board. The output capacitor in a SEPIC regulator experiences high RMS ripple currents, as shown in Figure 17. The RMS output capacitor ripple current is:
IRMS(COUT) = IO(MAX) * VO VIN(MIN)
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Note that the ripple current ratings from capacitor manufacturers are often based on only 2000 hours of life. This makes it advisable to further derate the capacitor or to choose a capacitor rated at a higher temperature than required. Several capacitors may also be placed in parallel to meet size or height requirements in the design. Manufacturers such as Nichicon, United Chemicon and Sanyo should be considered for high performance throughhole capacitors. The OS-CON semiconductor dielectric capacitor available from Sanyo has the lowest product of ESR and size of any aluminum electrolytic, at a somewhat higher price. In surface mount applications, multiple capacitors may have to be placed in parallel in order to meet the ESR or RMS current handling requirements of the application. Aluminum electrolytic and dry tantalum capacitors are both available in surface mount packages. In the case of tantalum, it is critical that the capacitors have been surge tested for use in switching power supplies. An excellent
27
LTC1871
APPLICATIO S I FOR ATIO
choice is AVX TPS series of surface mount tantalum. Also, ceramic capacitors are now available with extremely low ESR, ESL and high ripple current ratings. SEPIC Converter: Input Capacitor Selection The input capacitor of a SEPIC converter is less critical than the output capacitor due to the fact that an inductor is in series with the input and the input current waveform is triangular in shape. The input voltage source impedance determines the size of the input capacitor which is typically in the range of 10F to 100F. A low ESR capacitor is recommended, although it is not as critical as for the output capacitor. The RMS input capacitor ripple current for a SEPIC converter is: IRMS(CIN) = 1 12 * IL
Please note that the input capacitor can see a very high surge current when a battery is suddenly connected to the input of the converter and solid tantalum capacitors can fail catastrophically under these conditions. Be sure to specify surge-tested capacitors! SEPIC Converter: Selecting the DC Coupling Capacitor The coupling capacitor C1 in Figure 16 sees nearly a rectangular current waveform as shown in Figure 17. During the switch off-time the current through C1 is IO(VO/ VIN) while approximately - IO flows during the on-time. This current waveform creates a triangular ripple voltage on C1: VC1(P-P) = IO(MAX) C1 * f * VO VIN + VO + VD
The maximum voltage on C1 is then:
VC1(MAX) = VIN + VC1(P-P) 2
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which is typically close to VIN(MAX). The ripple current through C1 is:
IRMS(C1) = IO(MAX) * VO + VD VIN(MIN)
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The value chosen for the DC coupling capacitor normally starts with the minimum value that will satisfy 1) the RMS current requirement and 2) the peak voltage requirement (typically close to VIN). Low ESR ceramic and tantalum capacitors work well here. SEPIC Converter Design Example The design example given here will be for the circuit shown in Figure 18. The input voltage is 5V to 15V and the output is 12V at a maximum load current of 1.5A (2A peak). 1. The duty cycle range is:
VO + VD D= = 45.5% to 71.4% VIN + VO + VD
2. The operating mode chosen is pulse skipping, so the MODE/SYNC pin is shorted to INTVCC. 3. The operating frequency is chosen to be 300kHz to reduce the size of the inductors; the resistor from the FREQ pin to ground is 80k. 4. An inductor ripple current of 40% is chosen, so the peak input current (which is also the minimum saturation current) is:
V +V IL1(PEAK) = 1 + * IO(MAX) * O D 2 VIN(MIN) 12 + 0.5 0.4 = 1+ = 4.5A * 1.5 * 2 5
The inductor ripple current is: IL = * IO(MAX) * DMAX 1 - DMAX 0.714 = 0.4 * 1.5 * = 1.5A 1 - 0.714
LTC1871
APPLICATIO S I FOR ATIO
And so the inductor value is: L=
VIN(MIN) 5 * DMAX = * 0.714 = 4H 2 * IL * f 2 * 1.5 * 300k
The component chosen is a BH Electronics BH5101007, which has a saturation current of 8A. 5. With an minimum input voltage of 5V, only logic-level power MOSFETs should be considered. Because the maximum duty cycle is 71.4%, the maximum SENSE pin threshold voltage is reduced from its low duty cycle typical value of 150mV to approximately 120mV. Assuming a MOSFET junction temperature of 125C, the room temperature MOSFET RDS(ON) should be less than:
R3 1M 1 2 RC 33k CC1 R1 6.8nF 12.1k 1% R2 105k 1% 10 9
RUN ITH
LTC1871 3 4 RT 80.6k 1% 5 FB FREQ MODE/SYNC INTVCC GATE GND 8 7 6 CVCC 4.7F X5R M1 L2*
CC2 47pF
CIN, COUT1: KEMET T495X476K020AS CDC, COUT2: TAIYO YUDEN TMK432BJ106MM D1: INTERNATIONAL RECTIFIER 30BQ040
Figure 18a. 4.5V to 15V Input, 12V/2A Output SEPIC Converter
100 95 90 85 EFFICIENCY (%) 80 75 70 65 60 55 50 45 0.001 VO = 12V MODE = INTVCC 0.01 0.1 1 OUTPUT CURRENT (A) 10
1871 F18b
Figure 18b. SEPIC Efficiency vs Output Current
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RDS(ON) VSENSE(MAX) 1 * IO(MAX) 1 + * T 2 * 1 VO + VD V +1 IN(MIN) = 0.12 1 1 * * = 12.7m 1.5 1.2 * 1.5 12.5 +1 5
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For a SEPIC converter, the switch BVDSS rating must be greater than VIN(MAX) + VO, or 27V. This comes close to an IRF7811W, which is rated to 30V, and has a maximum room temperature RDS(ON) of 12m at VGS = 4.5V.
*
L1* SENSE VIN CDC 10F 25V X5R
VIN 4.5V to 15V
D1
+
COUT1 47F 20V x2
VOUT 12V 1.5A (2A PEAK) COUT2 10F 25V X5R x2 GND
1871 F018a
+
CIN 47F
*
L1, L2: BH ELECTRONICS BH510-1007 (*COUPLED INDUCTORS) M1: INTERNATIONAL RECTIFIER IRF7811W
VIN = 12V VIN = 4.5V VIN = 15V
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LTC1871
APPLICATIO S I FOR ATIO
VIN = 4.5V VOUT = 12V VOUT (AC) 200mV/DIV
IOUT 0.5A/DIV
50s/DIV
1871 F19a
Figure 19. LTC1871 SEPIC Converter Load Step Response
6. The diode for this design must handle a maximum DC output current of 2A and be rated for a minimum reverse voltage of VIN + VOUT, or 27V. A 3A, 40V diode from International Rectifier (30BQ040) is chosen for its small size, relatively low forward drop and acceptable reverse leakage at high temp. 7. The output capacitor usually consists of a high valued bulk C connected in parallel with a lower valued, low ESR ceramic. Based on a maximum output ripple voltage of 1%, or 120mV, the bulk C needs to be greater than:
COUT IOUT(MAX) = 0.01 * VOUT * f 1.5A = 41F 0.01 * 12V * 300kHz
The RMS ripple current rating for this capacitor needs to exceed: IRMS(COUT) IO(MAX) * 1.5A * 12V = 2.3A 5V VO VIN(MIN) =
To satisfy this high RMS current demand, two 47F Kemet capacitors (T495X476K020AS) are required. As a result, the output ripple voltage is a low 50mV to 60mV. In parallel with these tantalums, two 10F, low ESR (X5R) Taiyo Yuden ceramic capacitors (TMK432BJ106MM) are added for HF noise reduction.
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VIN = 15V VOUT = 12V VOUT (AC) 200mV/DIV IOUT 0.5A/DIV 50s/DIV
1871 F19b
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Check the output ripple with a single oscilloscope probe connected directly across the output capacitor terminals, where the HF switching currents flow. 8. The choice of an input capacitor for a SEPIC converter depends on the impedance of the source supply and the amount of input ripple the converter will safely tolerate. For this particular design and lab setup, a single 47F Kemet tantalum capacitor (T495X476K020AS) is adequate. As with the output node, check the input ripple with a single oscilloscope probe connected across the input capacitor terminals. If any HF switching noise is observed it is a good idea to decouple the input with a low ESR, X5R ceramic capacitor as close to the VIN and GND pins as possible. 9. The DC coupling capacitor in a SEPIC converter is chosen based on its RMS current requirement and must be rated for a minimum voltage of VIN plus the AC ripple voltage. Start with the minimum value which satisfies the RMS current requirement and then check the ripple voltage to ensure that it doesn't exceed the DC rating. IRMS(CI) IO(MAX) * = 1.5A * VO + VD VIN(MIN) 12V + 0.5V = 2.4A 5V
For this design a single 10F, low ESR (X5R) Taiyo Yuden ceramic capacitor (TMK432BJ106MM) is adequate.
LTC1871
TYPICAL APPLICATIO S
2.5V to 3.3V Input, 5V/2A Output Boost Converter
VIN 2.5V to 3.3V L1 1.8H 1 2 RC 22k CC1 R1 6.8nF 12.1k 1% R2 37.4k 1% RUN ITH LTC1871 3 4 RT 80.6k 1% 5 FB FREQ MODE/SYNC INTVCC GATE GND 8 7 6 CVCC 4.7F X5R M1 SENSE VIN 10 9 VOUT 5V 2A COUT2 10F 6.3V X5R x2 GND
1871 TA01a
CC2 47pF
CIN: COUT1: COUT2: CVCC:
SANYO POSCAP 6TPA47M SANYO POSCAP 6TPB150M TAIYO YUDEN JMK316BJ106ML TAIYO YUDEN LMK316BJ475ML
EFFICIENCY (%)
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D1
+
COUT1 150F 6.3V x2
+
CIN 47F 6.3V
D1: INTERNATIONAL RECTIFIER 30BQ015 L1: TOKO DS104C2 B952AS-1R8N M1: SILICONIX/VISHAY Si9426
Output Efficiency at 2.5V and 3.3V Input
100 95 90 85 80 75 70 65 60 55 50 0.001 0.01 0.1 1 OUTPUT CURRENT (A) 10
1871 TA01b
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LTC1871
TYPICAL APPLICATIO S
18V to 27V Input, 28V Output, 400W 2-Phase, Low Ripple, Synchronized RF Base Station Power Supply (Boost)
VIN 18V to 27V R2 8.45k 1% R1 93.1k 1% 1 2 CC1 47pF RUN ITH LTC1871 3 4 CFB1 47pF RT1 150k 5% 5 FB FREQ MODE/SYNC INTVCC GATE GND 8 7 6 CVCC1 4.7F X5R CIN2 2.2F 35V X5R M1 RS1 0.007 1W COUT5* 330F 50V x4 SENSE VIN 10 9 COUT1 2.2F 35V X5R x3 L1 5.6H L2 5.6H D1
1 2 RC 22k
RUN ITH
CC2 47pF R4 261k 1%
3 CFB2 47pF R3 12.1k 1% 4 RT2 150k 5% 5
FB FREQ MODE/SYNC
CC3 6.8nF
CIN1: CIN2, 3: COUT2, 4, 5: COUT1, 3, 6: CVCC1, 2:
SANYO 50MV330AX TAIYO YUDEN GMK325BJ225MN SANYO 50MV330AX TAIYO YUDEN GMK325BJ225MN TAIYO YUDEN LMK316BJ475ML
5V to 12V Input, 12V/0.2A Output SEPIC Converter with Undervoltage Lockout
*
L1* 1 2 RC 22k CC1 R4 6.8nF 127 1% R3 1.10k 1% RUN ITH LTC1871 3 4 RT 60.4k 1% 5 FB FREQ MODE/SYNC INTVCC GATE GND 8 7 6 CVCC 4.7F 10V X5R CIN1 1F 16V X5R M1 L2* SENSE VIN 10 9 COUT1 4.7F 16V X5R x3 CDC1 4.7F 16V X5R VIN 5V to 12V
R2 54.9k 1%
R1 127k 1%
CC2 100pF
NOTE: 1. VIN UVLO + = 4.47V VIN UVLO- = 4.14V
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+
CIN1 330F 50V
+
COUT2 330F 50V
GND
+
COUT6* 2.2F 35V X5R VOUT 28V 14A *L5, COUT5 AND COUT6 ARE AN OPTIONAL SECONDARY FILTER TO REDUCE OUTPUT RIPPLE FROM <500mVP-P TO <100mVP-P
1871 TA04
EXT CLOCK INPUT (200kHz) 10 9
L3 5.6H
L4 5.6H D2
SENSE VIN LTC1871 INTVCC GATE GND
8 7 6 CVCC2 4.7F X5R CIN3 2.2F 35V X5R M2 RS2 0.007 1W
COUT3 2.2F + 35V X5R x3
L5* 0.3H COUT4 330F 50V
L1 TO L4: L5: D1, D2: M1, M2:
SUMIDA CEP125-5R6MC-HD SUMIDA CEP125-0R3NC-ND ON SEMICONDUCTOR MBR2045CT INTERNATIONAL RECTIFIER IRLZ44NS
D1
VOUT1 12V 0.4A
+
CIN2 47F 16V AVX
*
RS 0.02
D1, D2: MBS120T3 L1 TO L3: COILTRONICS VP1-0076 (*COUPLED INDUCTORS) M1: SILICONIX/VISHAY Si4840
CDC2 4.7F 16V X5R
D2 L3*
*
GND COUT2 4.7F 16V X5R VOUT2 x3 -12V 1871 TA03 0.4A
LTC1871
TYPICAL APPLICATIO S
4.5V to 28V Input, 5V/2A Output SEPIC Converter with Undervoltage Lockout and Soft-Start
R1 115k 1% 1 2 RC 12k CC1 8.2nF CC2 47pF R3 154k 1% R4 49.9k 1% RUN ITH LTC1871 3 4 RT 162k 1% 5 FB FREQ MODE/SYNC INTVCC GATE GND 8 7 6 CVCC 4.7F 10V X5R CIN1 2.2F 35V X5R M1 L2* SENSE VIN 10 9
R2 54.9k 1%
C1 4.7nF
R5 100 Q1 R6 750
C2 1F X5R
CIN1, CDC: CIN2: COUT1: COUT2: CVCC:
Soft-Start
VOUT 1V/DIV IOUT 2.2A 1A/DIV (DC) 0.5A
1ms/DIV
VOUT 100mV/DIV (AC)
IOUT 1A/DIV (DC)
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*
L1*
VIN 4.5V to 28V CDC 2.2F 25V X5R x3
D1
+
COUT1 330F 6.3V
VOUT 5V 2A (3A TO 4A PEAK) COUT2 22F 6.3V X5R GND
1871 TA02a
+
CIN2 22F 35V
*
NOTES: 1. VIN UVLO + = 4.17V VIN UVLO- = 3.86V 2. SOFT-START dVOUT/dt = 5V/6ms
TAIYO YUDEN GMK325BJ225MN AVX TPSE226M035R0300 SANYO 6TPB330M TAIYO YUDEN JMK325BJ226MN LMK316BJ475ML
D1: L1, L2: M1: Q1:
INTERNATIONAL RECTIFIER 30BQ040 BH ELECTRONICS BH510-1007 (*COUPLED INDUCTORS) SILICONIX/VISHAY Si4840 PHILIPS BC847BF
Load Step Response at VIN = 4.5V
VOUT 100mV/DIV (AC)
1871 TA02b
250s/DIV
1871 TA02c
Load Step Response at VIN = 28V
2.2A
0.5A
250s/DIV
1871 TA02d
33
LTC1871
TYPICAL APPLICATIO S
5V to 15V Input, - 5V/5A Output Positive-to-Negative Converter with Undervoltage Lockout and Level-Shifted Feedback
VIN 5V to 15V VOUT -5V 5A L2*
R2 68.1k C1 1% 1nF
R1 154k 1% 1 2 RUN ITH LTC1871 RC 10k 3 4 5 RT 80.6k 1% R4 10k 1% R3 10k 1% 6 1 FB FREQ MODE/SYNC INTVCC GATE GND 8 7 6 CVCC 4.7F 10V X5R SENSE VIN 10 9
CC2 330pF CC1 10nF
LT1783 3 2
CIN: CDC: COUT: CVCC:
TDK C5750X5R1C476M TDK C5750X7R1E226M TDK C5750X5R0J107M TAIYO YUDEN LMK316BJ475ML
D1: ON SEMICONDUCTOR MBRB2035CT L1, L2: COILTRONICS VP5-0053 (*3 WINDINGS IN PARALLEL FOR THE PRIMARY, 3 IN PARALLEL FOR SECONDARY) M1: INTERNATIONAL RECTIFIER IRF7822
34
-
+
U
*
L1*
*
CDC 22F 25V X7R M1 D1
COUT 100F 6.3V X5R x2
CIN 47F 16V X5R
GND C2 10nF R5 40.2k 1%
4
1871 TA05
LTC1871
PACKAGE DESCRIPTIO
5.23 (.206) MIN
0.50 3.05 0.38 (.0197) (.0120 .0015) BSC TYP RECOMMENDED SOLDER PAD LAYOUT WITHOUT EXPOSED PAD OPTION DETAIL "A" 0 - 6 TYP
0.254 (.010) GAUGE PLANE
0.18 (.007) SEATING PLANE 0.17 - 0.27 (.007 - .011) 0.13 0.05 (.005 .002)
MSOP (MS) 1001
NOTE: 1. DIMENSIONS IN MILLIMETER/(INCH) 2. DRAWING NOT TO SCALE 3. DIMENSION DOES NOT INCLUDE MOLD FLASH, PROTRUSIONS OR GATE BURRS. MOLD FLASH, PROTRUSIONS OR GATE BURRS SHALL NOT EXCEED 0.152mm (.006") PER SIDE 4. DIMENSION DOES NOT INCLUDE INTERLEAD FLASH OR PROTRUSIONS. INTERLEAD FLASH OR PROTRUSIONS SHALL NOT EXCEED 0.152mm (.006") PER SIDE 5. LEAD COPLANARITY (BOTTOM OF LEADS AFTER FORMING) SHALL BE 0.102mm (.004") MAX
Information furnished by Linear Technology Corporation is believed to be accurate and reliable. However, no responsibility is assumed for its use. Linear Technology Corporation makes no representation that the interconnection of its circuits as described herein will not infringe on existing patent rights.
U
MS Package 10-Lead Plastic MSOP
(Reference LTC DWG # 05-08-1661)
0.889 0.127 (.035 .005) 3.2 - 3.45 (.126 - .136) 3.00 0.102 (.118 .004) (NOTE 3) 10 9 8 7 6 0.497 0.076 (.0196 .003) REF 4.88 0.10 (.192 .004) 3.00 0.102 (.118 .004) NOTE 4 12345 0.53 0.01 (.021 .006) DETAIL "A" 1.10 (.043) MAX 0.86 (.034) REF 0.50 (.0197) TYP
35
LTC1871
TYPICAL APPLICATIO S
High Power SLIC Supply with Undervoltage Lockout
GND
R1 49.9k 1% CR 1nF CC2 100pF
R2 150k 1%
RUN ITH
LTC1871 RC 82k CC1 1nF FB FREQ RT 120k MODE/SYNC f = 200kHz INTVCC GATE GND
10k C8 0.1F
1
LT1783 3
2
1871 TA06
RELATED PARTS
PART NUMBER LT(R)1619 LTC1624 LTC1700 LTC1872 LT1930 LT1931 LTC3401/LTC3402 DESCRIPTION Current Mode PWM Controller Current Mode DC/DC Controller No RSENSE Synchronous Step-Up Controller SOT-23 Boost Controller 1.2MHz, SOT-23 Boost Converter Inverting 1.2MHz, SOT-23 Converter 1A/2A 3MHz Synchronous Boost Converters COMMENTS 300kHz Fixed Frequency, Boost, SEPIC, Flyback Topology SO-8; 300kHz Operating Frequency; Buck, Boost, SEPIC Design; VIN Up to 36V Up to 95% Efficiency, Operation as Low as 0.9V Input Delivers Up to 5A, 550kHz Fixed Frequency, Current Mode Up to 34V Output, 2.6V VIN 16V, Miniature Design Positive-to-Negative DC/DC Conversion, Miniature Design Up to 97% Efficiency, Very Small Solution, 0.5V VIN 5V
36
Linear Technology Corporation
1630 McCarthy Blvd., Milpitas, CA 95035-7417
(408) 432-1900 q FAX: (408) 434-0507
q
www.linear.com
-
*COILTRONICS VP5-0155 (PRIMARY = 3 WINDINGS IN PARALLEL)
+
U
*
4 VIN 7V TO 12V
D2 10BQ060
+
C3 10F 25V X5R VOUT1 -24V 200mA
+
CIN 220F 16V TPS
*
T1* 1, 2, 3 5
D3 10BQ060
+
*
C4 10F 25V X5R
+
COUT 3.3F 100V
SENSE VIN
*
C2 4.7F 50V IRL2910 X5R C1 4.7F X5R RS 0.012 6
D4 10BQ060
+
C5 10F 25V X5R RF2 196k 1%
+
RF1 10k 1% 6
VOUT2 -72V 200mA
4
sn1871 1871fs LT/TP 1001 2K * PRINTED IN USA
(c) LINEAR TECHNOLOGY CORPORATION 2001


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