ANALOG DEVICES LTC3311-1 2MHz Automotive Low EMI Buck Regulator User Manual
- June 16, 2024
- Analog Devices
Table of Contents
LTC3311-1 2MHz Automotive Low EMI Buck Regulator
User Manual
LTC3311-1 2MHz Automotive Low EMI Buck Regulator
DEMO MANUAL D C 3113A
LTC 3 311-1
3.3V to 1V at 12.5A, 2MHz Automotive
Low EMI Buck Regulator
DESCRIPTION
Demonstration Circuit 3113A features the LT C ® 3311-1, fixed 1V, 12.5A
synchronous step-down Silent Switcher ® operating as a 2MHz, 3V to 3.6V input,
1V/12.5A output buck regulator. The LTC3311-1 supports fixed 1V output voltage
with operating frequencies from 500kHz up to 5MHz. The LTC3311-1 is a compact,
ultralow emission, high efficiency, and high speed synchronous monolithic
step-down switching regulator. The LTC3311-1 has Active Voltage Positioning
(AVP) where the output voltage is dependent on load current. At light load,
the output voltage is regulated above the nominal value. At full load, the
output voltage is regulated below the nominal value. The DC load regulation is
adjusted to improve transient performance and reduce required output
capacitance.
DC3113A is set up to run in forced continuous mode with a 2MHz switching
frequency but can be configured to run at different switching frequencies, or
in pulse-skipping mode. The LTC3311-1 oscillator can also synchronize to an
external clock using MODE/SYNC turret, with the DC3113A default setup. Figure
7 shows the efficiency and power loss of the DC3113A with a 3.3V input in both
operation modes.
The DC3113A is optimized for a 4A to 12A, 8A/µs load step transient. A fast
load step transient circuit is placed on the back of the demo board to measure
the load step response of the converter.
The DC3113A also has an EMI filter to reduce conducted EMI. This EMI filter
can be included by applying the input voltage at the VIN EMI terminal. The EMI
performance of the board is shown in the EMI TEST RESULTS section.
The red lines in the EMI performance graphs illustrate the CISPR25 Class 5
peak limits for the conducted and radiated emission tests.
The LTC3311-1 data sheet gives a complete description of the part and its
application information. The data sheet must be read in conjunction with this
demo manual. The LTC3311-1 is assembled in a 3mm × 3mm LQFN package with
exposed pads for low thermal resistance. The layout recommendations for low
EMI operation and maximum thermal performance are available in the data sheet
section Low EMI PCB Layout.
Design files for this circuit board are available.
All registered trademarks and trademarks are the property of their respective
owners.
PERFORMANCE SUMMARY
Specifications are at TA = 25°C
SYMBOL| PARAMETER| CONDITIONS| MIN| TYP| MAX|
UNITS
---|---|---|---|---|---|---
VIN/VIN EMI| DC3113A Input Voltage Range| | 3.0| | 3.6| V
VOUT_TYP| DC3113A Typical Output Voltage| IOUT = 8A| 0.990| 1.000| 1.010| V
VOUT_NO_LOAD| DC3113A Output Voltage with No Load| IOUT = 0A| 1.005| 1.016|
1.027| V
VOUT_FULL_LOAD| DC3113A Output Voltage with Full Load| IOUT = 12.5A| 0.980|
0.991| 1.001| V
VAVP| VOUT Active Voltage Positioning| |
2
| mV/A
IOUT| DC3113A Output Current| |
12.5
| A
fSW| Switching Frequency| | 1.8| 2| 2.2| MHz
EFF| Efficiency| VIN = 3.3V, IOUT = 5A| 90| %
BOARD PHOTO
Part marking is either ink mark or laser mark
QUICK START PROCEDURE
Refer to Figure 2 for the proper measurement equipment setup and follow the
procedure below:
NOTE: For accurate VIN, VOUT and efficiency measurements, measure VIN at the
VIN SNSE and GND SNSN turrets, and measure VOUT at the VOUT SNSE and GND SNSE
turrets as illustrated as VM1 and VM2 in Figure 2. When measuring the input or
output ripple, care must be taken to avoid a long ground lead on the
oscilloscope probe.
- Set the JP1 Jumper to the HI position.
- With power off, connect the input power supply to VIN and GND. If the input EMI filter is desired, connect the input power supply to VIN EMI and GND.
- Set power supply PS1 current limit to 10A. Set the electronic load LD1 to CC mode and 0A current. Slowly increase PS1 to 1V. If PS1 output current reads less than 20mA, increase PS1 to 3.3V. Verify that VM1 reads 3.3V and VM2 reads around 764mV. Check VM1, VM2, VM3, PS1 output current and LD1 input current. Connect an oscilloscope voltage probe as shown in Figure 3 or Figure 4. Set Channel to AC-coupled, voltage scale to 20mV and time base to 10µs. Check VOUT ripple voltage. Verify that PGOOD voltage is above 3V.
- Increase the load by 1A intervals up to 12.5A and observe the voltage output regulation, ripple voltage, and the voltage on the SSTT turret. Calculate Die temperature using the formula below:
- If pulse-skipping mode is desired, set PS1 to 0V. Install a 0Ω resistor in the R5 location and remove R3. Repeat steps 1 through 4. In step 4, observe that the switching waveform is now in pulse-skipping mode at light load.
- Optional: To change the frequency, remove R4 and R5, if installed. Install the desired RT resistor in the R6 location. Note that the MODE/SYNC pin should have high impedance to GND and VIN. Size the inductor, output capacitors and compensation components to provide the desired inductor ripple and a stable output. Refer to the LTC3311-1 data sheet and LTPowerCAD ® for more information on choosing the required components.
- To test the transient response with a base load, add the desired resistor to produce a minimum load between VOUT and I_STEP turrets (RL shown on Figure 2). Note that the total load resistance will be RL plus R10 (10mΩ). Adjust a signal generator with a 10ms period, 10% duty cycle and an amplitude from 1V to 2V to start.
- Measure the I_STEP voltage to observe the current, VI_STEP/10mΩ. Adjust the amplitude of the pulse to provide the desired transient. Connect signal generator SG1 between SG_INPUT and GND turrets. Adjust the rising and falling edge of the pulse to provide the desired ramp rate. Figure 8 shows a load step from 4A to 12A. Refer to the following equations:
- When done, turn off SG1, PS1 and Load. Remove all the connections to the demo board.
TEST SETUP
THEORY OF OPERATION
Introduction to the DC3113A
The DC3113A demonstration circuit features the LTC3311-1, a low voltage
synchronous step-down Silent Switcher. The LTC3311-1 is a monolithic, constant
frequency, current mode step-down DC/DC converter. An oscillator turns on the
internal top power switch at the beginning of each clock cycle. Current in the
inductor then increases until the top switch comparator trips and turnoff the
top power switch. The peak inductor current, at which the top switch turns
off, is controlled by the voltage on the ITH node. The error amplifier servos
the ITH node by comparing the voltage on the internal VFB node with an
internal 500mV reference. When the load current increases, it causes a
reduction in the feedback voltage relative to the reference, leading the error
amplifier to raise the ITH voltage until the average inductor current matches
the new load current. When the top switch turns off, the synchronous bottom
power switch turns on until the NeXT clock cycle begins. In pulse-skipping
mode, the bottom switch also turns off when inductor current falls to zero. If
overload conditions result in excessive current flowing through the bottom
switch, the next clock cycle will be delayed until the switch current returns
to a safe level.
If the EN pin is low, the LTC3311-1 is in shutdown state with low quiescent
current. When the EN pin is above its threshold, the switching regulator will
be enabled.
The MODE/SYNC pin synchronizes the switching frequency to an external clock.
It can be a clock output for multi-phase operation. It also sets the regulator
operation modes. The operation modes are either forced continuous or pulse-
skipping. See the LTC3311-1 data sheet for more detailed information.
The maximum allowable operating frequency is influenced by the minimum on time
of the top switch, the ratio of VOUT to VIN and the inductance of the output
inductor. The maximum allowable operating frequency may be calculated in the
formula below.
Select an operating switching frequency below fSW(MAX). It is desired to obtain an inductor current of 30% of the maximum LTC3311-1 operating load, 12.5A. Use the formulas below to calculate the inductor value to obtain a 30% (3A) inductor ripple for the operating frequency.
When determining the compensation components, C10, C11 and R8, controlling the
loop stability and transient response are the two main considerations. The
LTC3311-1 has been designed to operate at a high bandwidth for fast transient
response capabilities. This reduces required output capacitance to meet the
desired transient voltage range. The mid-band gain of the loop increases with
R8 and the bandwidth of the loop increases with decreasing C11. C10 along with
R8 provides a high frequency pole to reduce the high frequency gain.
Loop stability is generally measured using the Bode Plot method of plotting
loop gain in dB and phase shift in degrees. The 0dB crossover frequency should
be less than 1/6 of the operating frequency to reduce the effects of added
phase shift of the modulator. The control loop phase margin goal should be
45° or greater and a gain margin goal of 8dB or greater.
TYPICAL PERFORMANCE CHARACTERISTICS
EMI TEST RESULTS
PARTS LIST
ITEM| QTY| REFERENCE| PART DESCRIPTION|
MANUFACTURER/PART NUMBER
---|---|---|---|---
Required Circuit Components
1| 2| C2, C3| CAP, 22p F, X7S, 6.3V, 20%, 0805| TDK, C2012X7S0J226M125AC
2| 3| C4, C12, C20| CAP, 0.1 pF, X7S, 16V, 10%, 0201| MURATA, GRM033C71 C1
04KE14D
3| 5| C5, C6, C21-C23| CAP, 47p F, X7S, 6.3V, 20%, 1206| TDK,
C3216X7S0J476M160AC
4| 1| C9| CAP, 0.033pF, X7R, 25V, 10%, 0402| KEMET, C0402 C333K3RACTU
5| 1| C10| CAP., 6.8pF, COG/NPO, 50V, ±0.5pF, 0402| AVX, 04025A6R8DAT2A
6| 1| C11| CAR, 330pF, X7R, 50V, 10%, 0402, AEC-0200| TDK,
CGA2B2X7R1H331K050BA
7| 1| C19| CAP, 2.2pF, X7S, 10V,10%, 0402, AEC-0200| MURATA,
GRT155C71A225KE13D
8| 1| C24| CAP, 0.1 pF, X7R, 16V, 10%, 0402, AEC-0200| MURATA,
GCM155R71C104KA55D
9| 1| L1| IND., 0.08pH, PWR, 20%, 21.4A, 1.8m52, 4mm x 4mm, AEC-0200|
COILCRAFT XEL4020-800MEC
10| 1| R8| RES., 10k, 1%, 1/16W, 0402, AEC-0200| VISHAY, CRCW040210K0FKED
11| 1| U1| IC, LOW VOLTAGE SYNCH STEPDOWN REG, LOFN-18, PRELIM-PART NOT FOR
PRODUCTION| ADI APPROVED SUPPLIER, LTC3311JV-10BF
Additional Demo Board Circuit Components
1| 2| C1, C18| CAP., 470pF, TANT, POSCAP 6.3V, 20%, 7343, 10ma TCF| PANASONIC,
6TCF470MAH
2| 2| C7, C15| CAP, 0.1 pF, X7R, 10V, 10%, 0402, AEC-0200| MURATA, GCM155R71A1
04KA55D
3| 1| C8| CAP, 22p F, X7S, 6.3V, 20%, 0805| TDK, C2012X7S0J226M125AC
4| 4| C13, C14, C16, C17| CAP, 10p F, X7S, 6.3V, 20%, 0603| TDK,
C1608X7S0J106M080AC
5| 2| C25, C26| CAP, 0.22pF, X7R, 6.3V, 20%, 0603| JOHANSON DIELECTRICS,
6R3X14W224MV4
6| 1| C27| CAP, 2.2pF, X7S, 10y, 10%, 0402, AEC-0200| MURATA,
GRT155C71A225KE13D
7| 1| L2| IND., 1000 AT 100MHz, FERRITE BEAD, 25%, 8A, 6m0, 1812| WURTH
ELEKTRONIK, 74279226101
8| 1| 1| XSTR., MOSFET, N-CHAN, 25V, 100A, TDSON-8 pin| INFINEON, BSCO1ONE2LSI
9| 1| R1| RES., 1M, 1%, 1/16W, 0402, AEC-0200| STACKPOLE ELECTRONICS, INC.,
RMCF0402FT1M00
10| 1| R2| RES., 249k, 1%, 1/16W, 0402, AEC-0200| NIC, NRCO4F2493TRF
11| 2| R3, R9| RES., 100k, 5%, 1/16W, 0402, AEC-0200| NIC, NRC04.1104TRF
12| 1| R4| RES., OD, 1/16W, 0402, AEC-0200| NIC, NRCO4ZOTRF
13| 1| R7| RES., 200, 1%, 1/16W, 0402, AEC-0200| NIC, NRCO4F2OROTRF
14| 1| R10| RES., 0.020, 1%, 10W, 2818, HP METAL, SENSE, AEC-0200| VISHAY,
WSHP2818R0200FEA
15| 1| R11| RES., 10k, 5%, 1/16W, 0402, AEC-0200| NIC, NRC04.1103TRF
16| 0| TP1| CONN., U.FL, RECEPT ST SMD, 0Hz TO 66Hz 500| HIROSE ELECTRIC,
U.FL-R-SMT 1(10)
Hardware: For Demo Board Only
1| 12| El-E3, E5, E12, E14-E17, E20-E22| TEST POINT TURRET, 0.064″ MTG. HOLE,
PCB 0.062′ THK| MILL-MAX, 2308-2-00-80-00-00-07-0
2| 5| E4, El, El 0, El 3, El 8| TEST POINT TURRET 0.094″ MTG. HOLE, PCB 0.062″
THK| MILL-MAX, 2501-2-00-80-00-00-07-0
3| 5| E6, E8, E9, Ell, E19| CONN., BANANA JACK, FEMALE, THT NON- INSULATED,
SWAGE, 0.218″| KEYSTONE, 575-4
4| 1| JP1| CONN., HEIR, MALE, 1 x 3, 2mm, VERT, ST, THT| WURTH ELEKTRONIK,
62000311121
5| 4| MP1-MP4| STANDOFF NYLON, SNAP-ON, 0.50″| KEYSTONE, 8833
6| 1| XJP1| CONN., SHUNT FEMALE, 2-POS, 2mm| WURTH ELEKTRONIK, 60800213421
SCHEMATIC DIAGRAM
REVISION HISTORY
REV | DATE | DESCRIPTION | PAGE NUMBER |
---|---|---|---|
A | 3/23 | Updated Parts List Replaced Schematic Diagram | 8 9 |
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