TI1 M3000SQ/NOPB Dual synchronous emulated current-mode controller Datasheet

LM3000
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LM3000 Dual Synchronous Emulated Current-Mode Controller
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FEATURES
DESCRIPTION
•
•
•
•
•
The LM3000 is a dual output synchronous buck
controller which is designed to convert input voltages
ranging from 3.3V to 18.5V down to output voltages
as low as 0.6V. The two outputs switch at a constant
programmable frequency of 200 kHz to 1.5 MHz, with
the second output 180 degrees out of phase from the
first to minimize the input filter requirements. The
switching frequency can also be phase locked to an
external frequency. A CLKOUT provides an external
clock 90 degrees out of phase with the main clock so
that a second chip can be run out of phase with the
main chip. The emulated current-mode control utilizes
bottom side FET sensing to provide fast transient
response and current limit without the need for
external current sense resistors or RC networks.
Separate Enable, Soft-Start and Track pins allow
each output to be controlled independently to provide
maximum flexibility in designing system power
sequencing.
1
2
•
•
•
•
•
VIN Range FROM 3.3V to 18.5V
Output Voltage From 0.6V to 80% of VIN
Remote Differential Output Voltage Sensing
1% Accuracy at FB Pin
Interleaved Operation Reduces Input
Capacitors
Frequency Sync/Adjust From 200 kHz to 1.5
MHz
Startup With Pre-Bias Load
Independent Power Good, Enable, Soft-Start
and Track
Programmable Current Limit Without External
Sense Resistor
Hiccup Mode Short Circuit Protection
APPLICATIONS
•
•
•
•
•
•
DC Power Distribution Systems
Graphic Cards - GPU and Memory ICs
FPGA, CPLD, and ASICs
Embedded Processor
1.8V and 2.5V I/O Supplies
Networking Equipment (Routers, Hubs)
The LM3000 has a full range of protection features
which include input under-voltage lock-out (UVLO),
power good (PGOOD) signals for each output, overvoltage crowbar and hiccup mode during short circuit
events.
1
2
Please be aware that an important notice concerning availability, standard warranty, and use in critical applications of
Texas Instruments semiconductor products and disclaimers thereto appears at the end of this data sheet.
All trademarks are the property of their respective owners.
PRODUCTION DATA information is current as of publication date.
Products conform to specifications per the terms of the Texas
Instruments standard warranty. Production processing does not
necessarily include testing of all parameters.
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LM3000
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Simplified Application
VIN
CIN
L1
VOUT1
RFBT1
VIN
Q1
HG1
COUT1
RFBB1
LG1
Q2
LM3000
PGND1
LG2
Q4
VOUT2
COUT2
+
RFBT2
RFBB2
PGND2
GND1
GND2
EA1_GND
EA2_GND
FB2
FB1
PGOOD1
CSS1
CSYNC
SYNC
PGOOD2
EN1
EN2
SS1
SS2
CSS2
TRK2
TRK1
FREQ/SYNC
RFRQ
2
L2
VSW2
VSW1
+
Q3
HG2
CLKOUT
SGND
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VSW1
PGND1
LG1
VDR
VIN
LG2
PGND2
VSW2
Connection Diagram
8
7
6
5
4
3
2
1
ILIM1
9
32
ILIM2
HG1
10
31
HG2
30
VCB2
DAP (should be tied to SGND on
board)
13
28
CLKOUT
FB1
14
27
EA2_GND
COMP1
15
26
FB2
PGOOD1
16
25
COMP2
17
18
19
20
21
22
23
24
PGOOD2
EA1_GND
EN2
SGND
SS2
29
WQFN-32
5x5x0.8mm body size
0.5mm pitch
TRK2
LM3000
SS1
12
TRK1
VDD
EN1
11
FREQ/SYNC
VCB1
Figure 1. Top View
32-Lead WQFN
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PIN DESCRIPTIONS
Pin No.
(1)
4
Name
Description
1
VSW2
Switch node sense for channel 2.
2
PGND2
3
LG2
Channel 2 low-side gate drive for external MOSFET.
4
VIN
Chip supply voltage, input to the VDD and VDR regulators. (3.3V to 18.5V)
5
VDR
Supply for low-side gate drivers.
6
LG1
Channel 1 low-side gate drive for external MOSFET.
7
PGND1
8
VSW1
Switch node sense for channel 1.
9
ILIM1
Current limit setting input for channel 1.
10
HG1
Channel 1 high-side gate drive for external MOSFET.
11
VCB1
Boost voltage for channel 1 high-side driver.
12
VDD
Supply for control circuitry.
13
EA1_GND
14
FB1
15
COMP1
16
PGOOD1
17
FREQ/SYNC
Power ground for channel 2 low-side drivers. (1)
Power ground for channel 1 low-side drivers. (1)
Error amplifier ground sense for channel 1. (1)
Error amplifier input for channel 1.
Error amplifier output for channel 1.
Power good signal for channel 1 under-voltage and over-voltage.
Frequency set / synchronization input for internal PLL.
18
EN1
19
TRK1
Channel 1 enable input. Used to set the emulated current slope for channel 1.
20
SS1
21
TRK2
22
SS2
Channel 2 soft-start.
23
EN2
Channel 2 enable input. Used to set the emulated current slope for channel 2.
24
PGOOD2
25
COMP2
26
FB2
27
EA2_GND
28
CLKOUT
29
SGND
Local signal ground.*
30
VCB2
Boost voltage for channel 2 high-side driver.
31
HG2
Channel 2 high-side gate drive for external MOSFET.
32
ILIM2
Current limit setting input for channel 2.
DAP
Exposed die attach pad. Connect the DAP directly to SGND. (1)
Channel 1 track input.
Channel 1 soft-start.
Channel 2 track input.
Power good signal for channel 2 under-voltage and over-voltage.
Error amplifier output for channel 2.
Error amplifier input for channel 2.
Error amplifier ground sense for channel 2. (1)
Output clock. CLKOUT is shifted 90 degrees from SYNC input.
The LM3000 offers true remote ground sensing to achieve very tight line and load regulation. For best layout practice, the EA1_GND,
and EA2_GND should be tied to the ground end of the output capacitor (or output terminal) for VOUT1 and VOUT2 respectively. Inside the
LM3000, the two power ground nodes PGND1 and PGND2 are physically isolated from each other and also isolated from the internal
signal ground SGND. In order to achieve the best cross-channel noise rejection, it is advised to keep these three grounds isolated from
each other for the most part in the board layout and only tie them together at the ground terminals.
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These devices have limited built-in ESD protection. The leads should be shorted together or the device placed in conductive foam
during storage or handling to prevent electrostatic damage to the MOS gates.
Absolute Maximum Ratings (1) (2)
VIN to SGND, PGND
-0.3V to 20V
VSW1, VSW2 to SGND, PGND
-3V to 20V
(3)
-0.3V to 5.5V
VDD, VDR to SGND, PGND
VCB1, VCB2 to SGND ,PGND
24V
VCB1 to VSW1, VCB2 to VSW2
5.5V
FB1, FB2 to SGND, PGND
All other input pins to SGND, PGND
-0.3V to 3.0V
(4)
-0.3V to 5.5V
Junction Temperature (TJ-MAX)
150°C
Storage Temperature Range
-65°C to +150°C
Maximum Lead Temperature
Soldering, 5 seconds
260°C
ESD Rating
HBM (5)
2000V
(1)
(2)
(3)
(4)
(5)
Absolute Maximum Ratings indicate limits beyond which damage to the device may occur, including inoperability and degradation of
device reliability and/or performance. Functional operation of the device and/or non-degradation at the Absolute Maximum Ratings or
other conditions beyond those indicated in the Recommended Operating Conditions is not implied. Operating Range conditions indicate
the conditions at which the device is functional and the device should not be operated beyond such conditions. For ensured
specifications and conditions, see the Electrical Characteristics table.
If Military/Aerospace specified devices are required, please contact the Texas Instruments Sales Office/Distributors for availability and
specifications.
VDD and VDR are outputs of the internal linear regulator. Under normal operating conditions where VIN > 5.5V, they must not be tied to
any external voltage source. In an application where VIN is between 3.3V to 5.5V, it is recommended to tie the VDD, VDR and VIN pins
together, especially when VIN may drop below 4.5V. In order to have better noise rejection under these conditions, a 10Ω, 1μF input
filter may be used for the VDD pin.
HG1, HG2, LG1, LG2 and CLKOUT are all output pins and should not be tied to any external power supply. COMP1 and COMP2 are
also outputs and should not be tied to any lower output impedance power source. PGOOD1 and PGOOD2 are open drain outputs, with
a pull-down resistance of about 250Ω. Each of them may be tied to an external voltage source less than 5.5V through an external
resister greater than 3kΩ, although 10kΩ and above are preferred to reduce the necessary signal ground current.
Human Body Model (HBM) is 100 pF capacitor discharged through a 1.5k resistor into each pin. Applicable standard is JESD22-A114C.
Operating Ratings (1)
Input Voltage Range
VDD = VDR = VIN (2)
VIN
−40°C to +125°C
Junction Temperature (TJ) Range
(1)
(2)
3.3V to 5.5V
3.3V to 18.5V
Absolute Maximum Ratings indicate limits beyond which damage to the device may occur, including inoperability and degradation of
device reliability and/or performance. Functional operation of the device and/or non-degradation at the Absolute Maximum Ratings or
other conditions beyond those indicated in the Recommended Operating Conditions is not implied. Operating Range conditions indicate
the conditions at which the device is functional and the device should not be operated beyond such conditions. For ensured
specifications and conditions, see the Electrical Characteristics table.
VDD and VDR are outputs of the internal linear regulator. Under normal operating conditions where VIN > 5.5V, they must not be tied to
any external voltage source. In an application where VIN is between 3.3V to 5.5V, it is recommended to tie the VDD, VDR and VIN pins
together, especially when VIN may drop below 4.5V. In order to have better noise rejection under these conditions, a 10Ω, 1μF input
filter may be used for the VDD pin.
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Electrical Characteristics
Limits in standard type are for TJ = 25°C only; limits in boldface type apply over the junction temperature (TJ) range of -40°C
to +125°C. Minimum and Maximum limits are ensured through test, design, or statistical correlation. Typical values represent
the most likely parametric norm at TJ = 25°C, and are provided for reference purposes only. Unless otherwise noted, VIN =
12.0V, IEN1 = IEN2 = 40 µA.
Symbol
VFB
Parameter
Condition
FB Pin Voltage FB1, FB2 (LM3000A)
-20°C to +85°C
Min
Typ
Max
Units
0.594
0.6
0.606
V
0.591
0.6
0.609
0.591
0.6
0.609
0.6
0.612
VFB
FB Pin Voltage FB1, FB2 (LM3000)
-20°C to +85°C
ΔVFB/VFB
Line Regulation VDD = VIN = VDR
3.3V < VIN < 5.5, COMP = 1.5V
0.15
%
Line Regulation VIN > 6V
6V < VIN < 18.5V, COMP = 1.5V
0.3
%
Load Regulation
VIN = 12.0V, 1.0V < COMP < 1.4V
0.1
%
5
mA
0.588
Iq
VIN Operating Current
ISD
VIN Shutdown Current
IEN1 , IEN2 < 5 µA
50
IEN
EN Input Threshold Current
IEN Rising
15
ILIM
Source Current ILIM1, ILIM2
VILIM1, VILIM2 = 0V
17
ISS
Soft-Start Pull-Up Current
VSS = 0.5V
5.5
COMP Pin Hiccup Thresholds
COMP Threshold High
Hysteresis
VHICCUP
Hiccup Delay
tCOOL
Cool-Down Time Until Restart
VOVP
Over-Voltage Protection Threshold
µA
35
µA
20
23
µA
8.5
11.5
µA
10
Hysteresis
tDELAY
V
2.85
V
50
mV
16
Cycles
4096
As a % of Nominal Output Voltage
110
115
Cycles
120
%
Hysteresis
3
Under-Voltage Protection Threshold
As a % of REF1, REF2 (see Block
Diagram)
85
%
VCB Pin Leakage Current
VCB - VSW = 5.5V
250
nA
RDS1
Top FET Drive Pull-Up On-Resistance
VCB - VSW = 4.5V, VCB - HG = 100
mV
3
Ω
RDS2
Top FET Drive Pull-Down On-Resistance
VCB - VSW = 4.5V, HG - VSW = 100
mV
2
Ω
RDS3
Bottom FET Drive Pull-Up On-Resistance VDR - PGND = 5V, VDR - LG = 100
mV
2
Ω
RDS4
Bottom FET Drive Pull-Down OnResistance
VDR - PGND = 5V, LG - PGND = 100
mV
1
Ω
Switching Frequency
RFRQ = 100 kΩ
VUVP
GATE DRIVE
ICB
OSCILLATOR
fSW
RFRQ = 42.2 kΩ
230
425
RFRQ = 10 kΩ
VSYNC
Threshold for Synchronization at the
FREQ/SYNC Pin
Rising
1550
200
SYNC Pulse Width
100
Maximum Duty cycle
kHz
0.6
SYNC Range
DMAX
kHz
V
Falling
tSYNC
SYNC Rise/Fall Time
kHz
575
2.2
fSYNC
tSYNC-TRS
500
1500
kHz
ns
10
85
ns
%
ERROR AMPLIFIER
IFB
ISOURCE
ISINK
6
FB Pin Bias Current
FB = 0.6V
20
nA
COMP Pin Source Current
FB = 0.5V, COMP = 1.0V
80
µA
COMP Pin Sink Current
FB = 0.7V, COMP = 0.7V
80
µA
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Electrical Characteristics (continued)
Limits in standard type are for TJ = 25°C only; limits in boldface type apply over the junction temperature (TJ) range of -40°C
to +125°C. Minimum and Maximum limits are ensured through test, design, or statistical correlation. Typical values represent
the most likely parametric norm at TJ = 25°C, and are provided for reference purposes only. Unless otherwise noted, VIN =
12.0V, IEN1 = IEN2 = 40 µA.
Symbol
Parameter
VCOMP-HI
COMP Pin Voltage High Clamp
VCOMP-LO
COMP Pin Voltage Low Clamp
VOS-TRK
Condition
2.80
gm
Transconductance
Unity Gain Bandwidth Frequency
Typ
Max
Units
3.0
3.2
V
9.0
mV
0.48
Offset Using TRK Pin
fBW
Min
TRK = 0.45V
-9.0
0
V
1400
µS
10
MHz
INTERNAL VOLTAGE REGULATOR
VVDD
VVDD-ON
Internal Core Regulator Voltage
No External Load
5.15
V
UVLO Thresholds
VDD Rising
2.12
V
Hysteresis
0.14
1.1
V
VVDD-DO
Internal Core Regulator Dropout Voltage
No External Load
IVDD-ILIM
Internal Core Regulator Current Limit
VDD Short to Ground
80
mA
Regulator for External MOSFET Drivers
IVDR = 100 mA
5.2
V
VVDR-DO
Driver Regulator Dropout Voltage
IVDR = 100 mA
1.0
V
IVDR-ILIM
Driver Regulator Current Limit
VDR Short to Ground
450
mA
PGOOD On-Resistance
FB1 = FB2 = 0.47V
250
Ω
PGOOD High Leakage Current
VPGOOD = 5V
100
nA
WQFN-32 Package (1)
26.4
°C/W
VVDR
PGOOD OUTPUT
RPG-ON
IOH
THERMAL RESISTANCE
θJA
(1)
Junction-to-Ambient Thermal Resistance
Tested on a four layer JEDEC board. Four vias provided under the exposed pad. See JEDEC standards JESD51-5 and JESD51-7.
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Typical Performance Characteristics
8
3.3V Output Efficiency at 500 kHz
1.2V Output Efficiency at 500 kHz
Figure 2.
Figure 3.
3.3V Output Load and Line Regulation
1.2V Output Load and Line Regulation
Figure 4.
Figure 5.
FB1, FB2 Reference vs Temperature
VDD Voltage vs Temperature
Figure 6.
Figure 7.
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Typical Performance Characteristics (continued)
Soft-Start without Load
Pulse Skipping during Over-Current Condition
IL1 (5A/DIV)
VEN1 and VEN2 (5V/DIV)
VOUT1 (2V/DIV)
SW1 (5V/DIV)
VOUT2 (1V/DIV)
5 Ps/DIV
1 ms/DIV
Figure 8.
Figure 9.
No Load Soft-Start with Pre-Bias
Output Short Circuit Hiccup
VEN1 and VEN2 (5V/DIV)
VOUT1 (1V/DIV)
VOUT1 (1V/DIV)
VOUT2 (0.5V/DIV)
SW1 (10V/DIV)
1 ms/DIV
5 ms/DIV
Figure 10.
Figure 11.
Soft-Start with Load
Switch Node Short Circuit Hiccup
VEN1 and VEN2 (5V/DIV)
VOUT2 (1V/DIV)
VOUT1 (1V/DIV)
IL2 (10A/DIV)
VOUT2 (0.5V/DIV)
SW2 (5V/DIV)
1 ms/DIV
5 ms/DIV
Figure 12.
Figure 13.
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Typical Performance Characteristics (continued)
External Clock Synchronization
External Tracking
TRK1 (1V/DIV)
External Clock (1V/DIV)
FB1 (1V/DIV)
VOUT1 (2V/DIV)
VOUT1 (2V/DIV)
SW1 (10V/DIV)
5 Ps/DIV
10
20 ms/DIV
Figure 14.
Figure 15.
Error Amplifier Transconductance vs Temperature
Enable Current Threshold vs Temperature
Figure 16.
Figure 17.
Switching Frequency vs Temperature
RFRQ vs Switching Frequency
Figure 18.
Figure 19.
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BLOCK DIAGRAM
4 VIN
LG1
gmn
gm
LG1
IVIN
12 VDD
RDSON
5.2V
REGS
CURRENT
EMULATION
AND
SLOPE
COMPENSATION
ISLOPE2
1 kÖ 1 kÖ
7
VSW2
1
PGND2
2
ILIM1
9
ILIM2
32
SS2
22
TRK2
21
LG2
LG2
RDSON
SENSING
VBG
0.6V
BIAS
ASEN(s)
RAMP1
FREQ/
17 SYNC
PGND1
ASEN(s)
18 EN1
23 EN2
8
SENSING
ISLOPE1
5 VDR
VSW1
RAMP2
IFREQ
CLOCK/
PLL
++
28 CLKOUT
20 éA
+
-
OC1
++
20 éA
OC2
SYSTEM_CLOCK
+
-
SYSTEM_REF
20 SS1
8.5 éA
+
+
+
-
19 TRK1
REF1
EN2
or
FAULT
VSW1
EN1
11 VCB1
10 HG1
VSW1
14 FB1
REF1
VDR
EN2
VDR
PGND1
gm
+
+
FAULT
13 EA1_GND
EN1
VCB2
30
HG2
31
LG2
3
COMP2
25
FB2
26
VSW2
PGND2
gm
REF2
EA2_GND
27
PGOOD2
24
EN2
FB1
16 PGOOD1
FB2
VSW2
PWM LOGIC
DUTY CYCLE
AND
DRIVER
CONTROL
6 LG1
15 COMP1
REF2
EN1
or FAULT
FB1
8.5 éA
+
+
+
-
FB2
VOUT1, VOUT2
MONITOR
REF1
REF2
250Ö
250Ö
SYSTEM_REF
SGND
29
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FUNCTIONAL DESCRIPTION
THEORY OF OPERATION
The LM3000 is a dual emulated current-mode PWM synchronous controller. Unlike traditional peak current-mode
controllers which sense the current while the high-side FET is on, the LM3000 senses current while the low-side
FET is on. It then emulates the peak current waveform and uses that information to regulate the output voltage.
The blanking time when the high-side FET first turns on that is normally associated with high-side sensing is not
needed, allowing high-side ON pulses as low as 50 ns. The LM3000 therefore has both excellent line transient
response and the ability to regulate low output voltages from high input voltages.
STARTUP
After the EN1 or EN2 current exceeds the enable ON threshold and the voltage at the VDD pin reaches 2.2V, an
internal 8.5 µA current source charges the soft-start capacitor of the enabled channel. Once soft-start is complete
the converter enters steady state operation. Current limit is enabled during soft-start in case of a short circuit at
the output. The soft-start time is calculated as:
tSS =
CSS x 0.6V
8.5 éA
(1)
To avoid current limit during startup, the soft-start time tSS should be substantially longer than the time required
to charge COUT to VOUT at the maximum output current. To meet this requirement:
tSS >
VOUT x COUT
ILIMIT ± IOUT
(2)
STARTUP INTO OUTPUT PRE-BIAS
If the output capacitor of the LM3000 has been charged up to some pre-bias level before the converter is
enabled, the chip will force the soft-start capacitor to the same voltage as the FB pin. This will cause the output
to ramp up from the existing output voltage without discharging it. During the soft-start ramp, the low-side FET is
disabled whenever the COMP voltage is below the active regulation voltage range.
LOW INPUT VOLTAGE
The LM3000 includes an internal 5.2V linear regulator connected from the VIN pin to the VDD pin. This linear
regulator feeds the logic and FET drive circuitry. For input voltages less than 5.5V, the VIN, VDD and VDR pins
can be tied together externally. This allows the full input voltage to be used for driving the power FETs and also
minimizes conduction loss in the LM3000.
TRACKING
The LM3000 has individual tracking inputs which control each output during soft-start. This allows the output
voltage slew rates to be controlled for loads that require precise sequencing. When the tracking function is not
being used the TRK1 or TRK2 pins should be connected directly to the VDD pin.
During start-up, the error amplifier will follow the lower of the SS or TRK voltages. For design margin, the softstart time tSS should be set to 75% of the minimum expected rise time of the controlling supply. In the event that
the LM3000 is enabled with a pre-biased master supply controlling track, the soft-start capacitor will control the
tracking output voltage rise time. Pulling TRK down after a normal startup will cause the output voltage to follow
the track signal.
12
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VOUT1
RFBT1
VDD
FB1
RFBB1
TRK1
RT2
LM3000
VOUT2
TRK2
RFBT2
RT1
FB2
RFBB2
Figure 20. Tracking with VOUT1 Controlling VOUT2
Figure 20 shows a tracking example with the highest output voltage at VOUT1 controlling VOUT2. Tracking may be
set so that VOUT1 and VOUT2 both rise together. For this case, the equation governing the values of the tracking
divider resistors RT1 and RT2 is:
RT1
0.75 = VOUT1 x
RT1 + RT2
(3)
A value of 10 kΩ 1% is recommended for RT1 as a good compromise between high precision and low quiescent
current through the divider. Using an example of VOUT1 = 3.3V and VOUT2 = 1.2V, the value of RT2 is 34.4 kΩ 1%.
A timing diagram for VOUT1 controlling VOUT2 is shown in Figure 21. Note that the TRK pin must finish at least 100
mV higher than the 0.6V reference to achieve the full accuracy of the LM3000 regulation. To meet this
requirement the tracking voltage is offset by 150 mV. The tracking output voltage will reach its final value at 80%
of the controlling output voltage.
3.3V
0.8 x 3.3V
VOUT1
1.2V
VOUT2
Figure 21. Tracking with VOUT1 Controlling VOUT2
Alternatively, the tracking feature can be used to create equal slew rates for the output voltages. In order to track
properly, use the highest output voltage to control the slew rate. In this case, the tracking resistors are found
from:
RT1
VOUT2 = VOUT1 x
RT1 + RT2
(4)
Again, a value of 10 kΩ 1% is recommended for RT1. For the example case of VOUT1 = 5V and VOUT2 = 1.8V, RT2
is 17.8 kΩ 1%. A timing diagram for the case of equal slew rates is shown in Figure 22.
Either method ensures that the output voltage of the tracking supply always reaches regulation before the output
voltage of the controlling supply.
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5V
1.8V
VOUT1
1.8V
VOUT2
Figure 22. Tracking with Equal Slew Rates
The LM3000 can track the output of a master power supply by connecting a resistor divider to the TRK pins as
shown in Figure 23. For equal start times, the tracking resistors are determined by:
RT1
0.75 = VMASTER x
RT1 + RT2
(5)
VMASTER
MASTER
POWER
SUPPLY
VOUT1
RFBT1
FB1
RT2
RFBB1
TRK1
LM3000
VOUT2
TRK2
RFBT2
RT1
FB2
RFBB2
Figure 23. Tracking a Master Supply with Equal Start Time
5V
0.8 x 5V
VMASTER
3.3V
VOUT1
1.2V
VOUT2
Figure 24. Tracking a Master Supply with Equal Start Time
For equal slew rates, the circuit of Figure 25 is used. The relationship for the tracking divider is set by:
14
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VOUT1 = VMASTER x
VOUT2 = VMASTER x
RT1 + RT2
RT1 + RT2 + RT3
RT1
RT1 + RT2 + RT3
(6)
VMASTER
VOUT1
MASTER
POWER
SUPPLY
RFBT1
FB1
RT3
RFBB1
TRK1
LM3000
RT2
VOUT2
TRK2
RFBT2
RT1
FB2
RFBB2
Figure 25. Tracking a Master Supply with Equal Slew Rates
5V
3.3V
1.2V
VMASTER
3.3V
VOUT1
1.2V
VOUT2
Figure 26. Tracking a Master Supply with Equal Slew Rates
Continuous Conduction Mode
The LM3000 controls the output voltage by adjusting the duty cycle of the power MOSFETs with trailing edge
pulse width modulation. The output inductor and capacitor filter the square wave produced as the power
MOSFETs switch the input voltage, thereby creating a regulated output voltage. The dc level of the output
voltage is determined by feedback resistors using the following equation:
VOUT = 0.6 x
RFBB + RFBT
RFBB
(7)
The output inductor current can flow from the drain to the source of the low-side MOSFET, which keeps the
converter in continuous-conduction-mode (CCM). CCM has the advantage of constant frequency and nearly
constant duty cycle (D = VOUT / VIN) over all load conditions, and also allows the converter to sink current at the
output if needed.
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FREQUENCY SETTING
The switching frequency of the internal oscillator is set by a resistor, RFRQ, connected from the FREQ/SYNC pin
to SGND. The proper resistor for a desired switching frequency fSW can be selected from the curves in the
Typical Performance Characteristics section labeled “RFRQ vs Switching Frequency” or by using the following
equation:
RFRQ =
2.48 x 1010
- 1000
fSW
fSW x 1+
3.4 x 106
where
•
fSW is the switching frequency in Hz
(8)
FREQUENCY SYNCHRONIZATION
The switching frequency of the LM3000 can be synchronized by an external clock or other fixed frequency signal
in the range of 200 kHz to 1.5 MHz. The external clock should be applied through a 100 pF coupling capacitor as
shown in Figure 27. In order for the oscillator to synchronize properly, the minimum amplitude of the SYNC
signal is 2.2V and the maximum amplitude is VDD. The minimum pulse width both positive and negative is 100
ns. The nominal dc voltage at the FREQ/SYNC pin is 0.6V, which is also the clamp voltage level for the falling
edge of the SYNC pulse. Depending on the pulse width and frequency, CSYNC may be adjusted to provide
sufficient amplitude of the signal at the FREQ/SYNC. It is possible to drive this pin directly from a 0 to 2.2V logic
output, though not recommended for the typical application.
Circuits that use an external clock should still have a resistor RFRQ connected from the FREQ/SYNC pin to
ground. RFRQ is selected using the equation from the FREQUENCY SETTING section to match the external
clock frequency. This allows the controller to continue operating at approximately the same switching frequency if
the external clock fails and the coupling capacitor on the clock side is grounded or pulled to logic high.
In the case of no external clock edges at startup, the internal oscillator will be controlled by the external set
resistor until the first clock edge is detected. After the first edge, the PLL will lock within a few clock cycles, after
which any missing edges will cause the oscillator to be programmed by RFRQ. If RFRQ is chosen to program the
oscillator very close to the external clock frequency, the PLL will lock very quickly and there will be very little
disturbance in the switching frequency.
Care must be taken to prevent errant pulses from triggering the synchronization circuitry. In circuits that will not
synchronize to an external clock, CSYNC should be connected from the FREQ/SYNC pin to SGND as a noise
filter. When a clock pulse is first detected, the LM3000 begins switching at the external clock frequency. Noise or
a short burst of clock pulses may result in variations of the switching frequency due to loss of lock by the PLL.
LM3000
CSYNC
FREQ/SYNC
100 pF
EXTERNAL CLOCK
OR CLKOUT FROM
ANOTHER LM3000
RFRQ
Figure 27. Clock Synchronization Circuit
In the case where two LM3000 controllers are used, the CLKOUT of the first controller can be used as a
synchronization input for the second controller. Note that the CLKOUT is 90 degrees out of phase with the main
controller clock, so that the four phases of the two controllers are separated for minimum input ripple current.
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MOSFET GATE DRIVE
The LM3000 has two sets of gate drivers designed for driving N-channel MOSFETs in a synchronous mode.
Power for the high-side driver is supplied through the VCB pin. For the high-side gate HG to turn on the top FET,
the VCB voltage must be at least one VGS(th) greater than VIN. This voltage is supplied from a local charge pump
which consists of a Schottky diode and bootstrap capacitor, shown in Figure 28. For the Schottky, a rating of at
least 250 mA and 30V is recommended. A dual package may be used to supply both VCB1 and VCB2.
Both the bootstrap and the low-side FET driver are fed from VDR, which is the output of a 5V internal linear
regulator. This regulator has a dropout voltage of approximately 1V. The drive voltage for the top FET driver is
about VDR - 0.5 at light load condition and about VDR at normal to full load condition. This information is needed
to select the type of MOSFETs used, as well as calculate the losses in driving them.
D1
VDR
VCB
CBOOT
VIN
HG
VOUT
LM3000
SW
+
LG
Figure 28. Bootstrap Circuit
UVLO
For the case where VIN is > VDD, the VIN UVLO thresholds are determined by the VDD UVLO comparator and
the VDD dropout voltage. This sets the rising threshold for VIN at approximately 3V, with 30 mV of hysteresis.
For the case where VIN is < 5.5V and tied to VDD and VDR, the UVLO trip point is 2.12V rising. UVLO consists
of turning off the top and bottom FETs and remaining in that condition until VDD rises above 2.12V. The falling
trip point is 140 mV below the rising trip point.
CURRENT LIMIT
The current limit of the LM3000 is realized by sensing the current in the low-side FET while the output current
circulates through it. This voltage (IOUT x RDS(on)_LO) is compared against the voltage of a fixed, internal 20 µA
current source and a user-selected resistor, RLIM, connected between the switch node and the ILIM pin. Once a
current limit event is sensed, the high-side switch is disabled for the following cycle and the low-side FET is kept
on during this time. If sixteen consecutive current limit cycles occur, the part enters hiccup mode.
The value of RLIM for a desired current limit IILIMIT can be selected by the following equation:
ILIMIT x RDS(on)_LO
RLIM =
20 éA
(9)
HICCUP MODE
During hiccup mode the LM3000 disables both the high-side and low-side MOSFETs, and remains in this state
for 4096 switching cycles. After this cool down period the circuit restarts again through the normal soft-start
sequence. If the shorted fault condition persists, hiccup will retrigger once the soft-start has finished. This occurs
when the SS voltage is greater than 0.7V and switching has reached the continuous conduction mode state.
There is a coarse high-side current limit which senses the voltage across the high-side MOSFET. The threshold
is approximately 0.5V, which may provide some level of protection for a catastrophic fault. Hiccup will
immediately trigger after two consecutive high-side current limit fault events.
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POWER GOOD
Power good pins PGOOD1 and PGOOD2 are available to monitor the output status of the two channels
independently. The PGOOD1 pin connects to the output of an open drain MOSFET, which will remain open while
Channel 1 is within the normal operating range. PGOOD1 goes low (low impedance to ground) under the
following three conditions:
1. Channel 1 is turned off.
2. OVP on Channel 1.
3. UVP on Channel 1.
PGOOD2 functions in a similar manner. UVP tracks REF1, REF2 as shown in the block diagram. OVP sets a
fault which turns off the high gate and turns on the low gate. This discharges the output voltage until it has fallen
3% below the OVP threshold.
PGOOD may be pulled up through a resistor to any voltage which is < 5.5V. When using VDD for the pull-up
voltage, a typical value of 100 kΩ is used to minimize loading on VDD.
ENABLE
A fixed external voltage source and resistors to EN1 and EN2 are used to independently enable each output.
The LM3000 can be put into a low power shutdown mode by pulling the EN1 and EN2 pins to ground, or by
applying 0V to the enable resistors. During shutdown both the high-side and low-side FETs are disabled. The
quiescent current during shutdown is approximately 30 µA.
The enable pins also control the emulated current ramp amplitude by programming the current into EN1 and
EN2. The recommended range for IEN is 40 μA to 160 μA. See the Application Information section under
CONTROL LOOP COMPENSATION for the complete design method.
APPLICATION INFORMATION
The most common circuit controlled by the LM3000 is a non-isolated, synchronous buck regulator. The buck
regulator steps down the input voltage and has a duty ratio D of:
VOUT 1
x
D=
VIN K
where
•
η is the estimated converter efficiency
(10)
The following is a design example selecting components for the Typical Application Schematic of Figure 43. The
circuit is designed for two outputs of 3.3V at 8A and 1.2V at 15A from an input voltage of 6V to 18V. This circuit
is typical of a ‘brick’ module and has a height requirement of 6.5mm or less. Other assumptions used to aid in
circuit design are that the expected load is a small microprocessor or ASIC with fast load transients, and that the
type of MOSFETs used are in SO-8 or its equivalent packages such as PowerPAK ®, PQFN and LFPAK (LFPAKi).
SWITCHING FREQUENCY
The selection of switching frequency is based on the tradeoff between size, cost and efficiency. In general, a
lower frequency means larger, more expensive inductors and capacitors. A higher switching frequency generally
results in a smaller but less efficient solution, because the power MOSFET gate capacitances must be charged
and discharged more often in a given amount of time. For this application a frequency of 500 kHz is selected.
500 kHz is a good compromise between the size of the inductor and MOSFETs, transient response and
efficiency. Following the equation given for RFRQ in the FREQUENCY SETTING section, for 500 kHz operation a
42.2 kΩ 1% resistor is used.
MOSFETS
Selection of the power MOSFETs is governed by a tradeoff between size, cost and efficiency. Buck regulators
that use a controller IC and discrete MOSFETs tend to be most efficient for output currents of 4A to 20A.
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Losses in the high-side FET can be broken down into conduction loss, gate charge loss and switching loss.
Conduction, or I2R loss is approximately:
PCOND_HI = D x (IOUT2 x RDS(on)_HI x 1.3) (High-side FET)
PCOND_LO = D x (IOUT2 x RDS(on)_LO x 1.3) (Low-side FET)
(11)
(12)
In the above equations the factor 1.3 accounts for the increase in MOSFET RDS(on) due to self heating.
Alternatively, the 1.3 can be ignored and the RDS(on) of the MOSFET estimated using the RDS(on) vs. Temperature
curves in the MOSFET datasheets.
The gate charge loss results from the current driving the gate capacitance of the power MOSFETs, and is
approximated as:
PDR = VIN x (QG_HI + QG_LO) x fSW
(13)
Where QG_HI and QG_LO are the total gate charge of the high-side and low-side FETs respectively at the typical
5V driver voltage. Gate charge loss differs from conduction and switching losses in that the majority of dissipation
occurs in the LM3000.
The switching loss occurs during the brief transition period as the FET turns on and off, during which both current
and voltage are present in the channel of the FET. This can be approximated as the following:
PSW_ON = VIN x IL_VL x D x RG_ON
x
QGD
VDR - VPLT2
+ CISS x Ln
VDR - VTH
VDR ± VPLT1
(14)
PSW_OFF = VIN x IL_PK x E x RG_OFF
x
QGD
VPLT2
+ CISS x Ln
VPLT2
VTH
(15)
Where QGD is the high-side FET Miller charge with a VDS swing between 0 to VIN; CISS is the input capacitance of
the high-side MOSFET in its off state with VDS = VIN. α and β are fitting coefficient numbers, which are usually
between 0.5 to 1, depending on the board level parasitic inductances and reverse recovery of the low-side power
MOSFET body diode. Under ideal condition, setting α = β = 0.5 is a good starting point. Other variables are
defined as:
IL_VL = IOUT - 0.5 x ΔIL
IL_PK = IOUT + 0.5 x ΔIL
VPLT1
VPLT2
VTH +
(16)
(17)
IL_VL
gmFET_HI
(18)
IL_PK
VTH + g
mFET_HI
(19)
(20)
(21)
RG_ON = 8.5 + RG_INT + RG_EXT
RG_OFF = 2.8 + RG_INT + RG_EXT
Switching loss is calculated for the high-side FET only. 8.5 and 2.8 represent the LM3000 high-side driver
resistance in the transient region. RG_INT is the gate resistance of the high-side FET, and RG_EXT is the external
gate resistance if applicable. RG_EXT may be used to damp out excessive parasitic ringing at the switch node.
For this example, the maximum drain-to-source voltage applied to either MOSFET is 18V. The maximum drive
voltage at the gate of the high-side MOSFET is 5V, and the maximum drive voltage for the low-side MOSFET is
5V. The selected MOSFET must be able to withstand 18V plus any ringing from drain to source, and be able to
handle at least 5V plus ringing from gate to source. If the duty cycle of the converter is small, then the high-side
MOSFET should be selected with a low gate charge in order to minimize switching loss whereas the bottom
MOSFET should have a low RDSONto minimize conduction loss.
For a typical input voltage of 12V and output currents of 8A and 12A, the MOSFET selections for the design
example are HAT2168 for the high-side MOSFET and RJK0330DPB for the low-side MOSFET.
A 3Ω resistor for RCBT is added in series with the VDR regulator output, as shown in Figure 43. This helps to
control the MOSFET turn-on and ringing at the switch node, without affecting the MOSFET turn-off.
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To improve efficiency, 3A, 40V Schottky diodes are placed across the low-side MOSFETs. The external Schottky
diodes have a much lower forward voltage than the MOSFET body diode, and help to minimize the loss due to
the body diode recovery characteristic.
OUTPUT INDUCTORS
The first criterion for selecting an output inductor is the inductance itself. In most buck converters, this value is
based on the desired peak-to-peak ripple current, ΔIL that flows in the inductor along with the load current. As
with switching frequency, the selection of the inductor is a tradeoff between size and cost. Higher inductance
means lower ripple current and hence lower output voltage ripple. Lower inductance results in smaller, less
expensive devices. An inductance that gives a ripple current of 1/6 to 1/3 of the maximum output current is a
good starting point. (ΔIL = (1/6 to 1/3) x IOUT). Minimum inductance is calculated from this value, using the
maximum input voltage as:
LMIN =
VIN(MAX) - VOUT
xD
fSW x 'IL
(22)
By calculating in terms of amperes, volts, and megahertz, the inductance value will come out in micro henries.
The inductor ripple current is found from the minimum inductance equation:
VIN(MAX) - VOUT
xD
'IL =
fSW x LACTUAL
(23)
The second criterion is inductor saturation current rating. The LM3000 has an accurately programmed valley
current limit. During an instantaneous short, the peak inductor current can be very high due to a momentary
increase in duty cycle. Since this is limited by the coarse high-side switch current limit, it is advised to select an
inductor with a larger core saturation margin and preferably a softer roll off of the inductance value over load
current.
For the design example, standard values of 1.2 μH for the 1.2V, 15A output and 2.7 μH for the 3.3V, 8A output
are chosen to fall within the ΔIL = (1/6 to 1/3) x IOUT range.
The dc loss in the inductor is determined by its series resistance RL. The dc power dissipation is found from:
PDC = IOUT2 x RL
(24)
The ac loss can be estimated from the inductor manufacturer’s data, if available. The ac loss is set by the peakto-peak ripple current ΔIL and the switching frequency fSW.
OUTPUT CAPACITORS
The output capacitors filter the inductor ripple current and provide a source of charge for transient load
conditions. A wide range of output capacitors may be used with the LM3000 that provide excellent performance.
The best performance is typically obtained using aluminum electrolytic, tantalum, polymer, solid aluminum,
organic or niobium type chemistries in parallel with a ceramic capacitor. The ceramic capacitor provides
extremely low impedance to reduce the output ripple voltage and noise spikes, while the aluminum or other
capacitors provide a larger bulk capacitance for transient loading and series resistance for stability.
When selecting the value for the output capacitor the two performance characteristics to consider are the output
voltage ripple and transient response. The output voltage ripple can be approximated as:
'VO = 'IL x
2
RC +
1
2
8 x fSW x CO
where
•
•
•
•
•
20
ΔVO (V) is the peak to peak output voltage ripple
ΔIL (A) is the peak to peak inductor ripple current
RC (Ω) is the equivalent series resistance or ESR of the output capacitor
fSW (Hz) is the switching frequency
CO (F) is the output capacitance
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The amount of output ripple that can be tolerated is application specific. A general recommendation is to keep
the output ripple less than 1% of the rated output voltage. The output capacitor selection will also affect the
output voltage droop and overshoot during a load transient. The peak transient of the output voltage during a
load current step is dependent on many factors. Given sufficient control loop bandwidth an approximation of the
transient voltage can be obtained from:
2
2
L x 'IO
VP =
2 x C O x VL
+
RC x C O x V L
2xL
where
•
•
VP (V) is the output voltage transient
ΔIO (A) is the load current step change
(26)
CO (F) is the output capacitance, L (H) is the value of the inductor and RC (Ω) is the series resistance of the
output capacitor. VL (V) is the minimum inductor voltage, which is duty cycle dependent.
For D < 0.5, VL = VOUT
For D > 0.5, VL = VIN - VOUT
This shows that as the input voltage approaches VOUT, the transient droop will get worse. The recovery
overshoot remains fairly constant.
The loss associated with the output capacitor series resistance can be estimated as:
PCO = RC x
'IL
2
12
(27)
Output Capacitor Design Procedure
For the design example VIN = 12V, VOUT = 3.3V, D = VOUT / VIN = 0.275, L = 2.7 μH, ΔIL = 1.8A, ΔIO = 8A and VP
= 0.15V.
To meet the transient voltage specification, the maximum RC is:
VP
RC d
'IO
(28)
For the design example, the maximum RC is 18.75 mΩ. Choose RC = 15 mΩ as the design limit.
From the equation for VP, the minimum value of CO is:
2
CO t
L x 'IO
VP x VL
1
x
1+
1-
RC x 'IO
2
VP
(29)
For D < 0.5, VL = VOUT
For D > 0.5, VL = VIN - VOUT
With RC = VP / ΔIO this reduces to:
2
CO t
L x 'IO
VP x VL
(30)
With RC = 0 this reduces to:
2
CO t
L x 'IO
2 x VP x VL
(31)
Since D < 0.5, VL = VOUT. With RC = 15 mΩ, the minimum value for CO is 218 μF.
The minimum control loop bandwidth fC is given by:
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'IO
2 x S x C O x VP
(32)
For the design example, the minimum value for fC is 39 kHz. A 220 μF, 15 mΩ polymer capacitor in parallel with
a 22 μF, 3 mΩ ceramic will meet the target output voltage ripple and transient specification.
For the 1.2V, 15A output, two 220 μF, 15 mΩ polymer capacitors in parallel with a 22 μF, 3 mΩ ceramic are
chosen to meet the target design specifications.
INPUT CAPACITORS
The input capacitors for a buck regulator are used to smooth the large current pulses drawn by the inductor and
load when the high-side MOSFET is on. Due to this large ac stress, input capacitors are usually selected on the
basis of their ac rms current rating rather than bulk capacitance. Low ESR is beneficial because it reduces the
power dissipation in the capacitors. Although any of the capacitor types mentioned in the OUTPUT
CAPACITORS section can be used, ceramic capacitors are common because of their low series resistance. In
general the input to a buck converter does not require as much bulk capacitance as the output.
The input capacitors should be selected for rms current rating and minimum ripple voltage. The equation for the
rms current and power loss of the input capacitor in a single phase can be estimated as:
ICIN(RMS) | IO x D x (1 ± D)
2
PCIN | IO x D x (1 ± D) x RCIN
where
•
•
IO (A) is the output load current
RCIN (Ω) is the series resistance of the input capacitor
(33)
Since the maximum values occur at D = 0.5, a good estimate of the input capacitor rms current rating in a single
phase is one-half of the maximum output current.
Neglecting the series inductance of the input capacitance, the input voltage ripple for a single phase can be
estimated as:
'IL
IO x D x (1 ± D)
x RCIN
+ IO +
'VIN =
CIN x fSW
2
(34)
By defining the maximum input voltage ripple, the minimum requirement for the input capacitance can be
calculated as:
IO x D x (1 ± D)
CIN t
'VIN ± IO +
'IL
2
x RCIN x fSW
(35)
For the dual output design operating 180° out of phase, the general equation for the input capacitor rms current
is approximated as:
ICIN(RMS) |
(I12 x D1) + (I22 x D2)
+ (2 x I1 x I2 x D3)
± (I1 x D1 + I2 x D2)2
(36)
Where the output currents are I1, I2 and the duty cycles are D1, D2 respectively. D3 represents the overlapping
effective duty cycle, which adds to the RMS current.
D3 = MAX(MIN(D1 ± 0.5 , D2) , 0)
+ MAX(MIN(D2 ± 0.5 , D1) , 0)
(37)
If D > 0.5 for both or D < 0.5 for both, the worst case rms current occurs with one output at full load and the other
at no load. The maximum rms current can be approximated as:
ICIN(RMS)MAX | 0.5 x MAX(I1 , I2)
(38)
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If D > 0.5 for one and D < 0.5 for the other, the worst case rms current becomes:
I12 + I22
ICIN(RMS)MAX | 0.707 x
(39)
In most applications for point-of-load power supplies, the input voltage is the output of another switching
converter. This output often has a lot of bulk capacitance, which may provide adequate damping.
When the converter is connected to a remote input power source through a wiring harness, a resonant circuit is
formed by the line impedance and the input capacitors. If step input voltage transients are expected near the
maximum rating of the LM3000, a careful evaluation of the ringing and possible overshoot at the device VIN pin
should be completed. To minimize overshoot make CIN > 10 x LIN. The characteristic source impedance and
resonant frequency are:
LIN
ZS =
fS =
CIN
1
2 x S x LIN x CIN
(40)
The converter exhibits a negative input impedance which is lowest at the minimum input voltage:
ZIN = ±
VIN
2
POUT
(41)
The damping factor for the input filter is given by:
á=
1
x
2
RLIN + RCIN
ZS
+
ZS
ZIN
where
•
•
RLIN is the input wiring resistance
RCIN is the series resistance of the input capacitors
(42)
The term ZS / ZIN will always be negative due to ZIN.
When δ = 1, the input filter is critically damped. This may be difficult to achieve with practical component values.
With δ < 0.2, the input filter will exhibit significant ringing. If δ is zero or negative, there is not enough resistance
in the circuit and the input filter will sustain an oscillation.
When operating near the minimum input voltage, an aluminum electrolytic capacitor across CIN may be needed
to damp the input for a typical bench test setup. Any parallel capacitor should be evaluated for its rms current
rating. The current will split between the ceramic and aluminum capacitors based on the relative impedance at
the switching frequency. Using a square wave approximation, the rms current in each capacitor is found from:
C1 = CIN1 R1 = RCIN1 C2 = CIN2 R2 = RCIN2
X1 |
1
2.2 x S x fSW x C1
X2 |
1
2.2 x S x fSW x C2
ICIN(RMS) x
ICIN1(RMS) =
2
R2 + X2
2
2
2
(R1 + R2) + (X1 + X2)
ICIN(RMS) x
ICIN2(RMS) =
2
R1 + X1
2
2
2
(R1 + R2) + (X1 + X2)
(43)
Input Capacitor Design Procedure
Ceramic capacitors are sized to support the required rms current. Aluminum electrolytic capacitors are used for
damping. Treating each phase separately, find the minimum value for the ceramic capacitor from:
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SNVS612B – JULY 2009 – REVISED APRIL 2013
CIN t
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IO x D x (1 ± D)
'VIN x fSW
(44)
For the design example allowing 0.25V input voltage ripple, the worst case occurs for the 3.3V, 8A output at D =
0.5. The minimum value is CIN = 16 μF. For the 1.2V, 15A output, the worst case D = 1.2V / 6V = 0.2. Then CIN =
4.8 μF. Find the rms current rating for each from:
ICIN(RMS) | IO x D x (1 ± D)
(45)
Using the same criteria, results are 4A rms for the 3.3V phase and 3A rms for the 1.2V phase. Manufacturer data
for 10 μF, 25V, X5R capacitors in a 1206 package allows for 3A rms with a 20°C temperature rise. For the
design example, using two ceramic capacitors for each phase will meet both the input voltage ripple and rms
current target. Since the series resistance is so low at about 5 mΩ per capacitor, a parallel aluminum electrolytic
is used for damping. A good general rule is to make the damping capacitor at least five times the value of the
ceramic. By sizing the aluminum such that it is primarily resistive at the switching frequency, the design is greatly
simplified since the ceramic is primarily reactive. In this case the approximation for the rms current in the
damping capacitor is:
ICIN(RMS)
ICIN2(RMS) |
2.2 x S x fSW x RCIN2 x CIN1
where
•
•
•
CIN2 is the damping capacitance
RCIN2 is its series resistance
CIN1 is the ceramic capacitance
(46)
A 150 μF, 50V, 0.18Ω, 670 mA capacitor in a 10 mm x 10.2 mm package is chosen for each input. Calculated
rms current for the 3.3V phase is 322 mA, with 242 mA calculated for the 1.2V phase.
CURRENT LIMIT
For the design example, the desired current limit set point is chosen to be 150% of the maximum load current.
To account for the tolerance of the internal current source and allowing RDS(on) = 4 mΩ for the low-side MOSFET
at elevated temperature, a target of 23A is used for the 1.2V output, with 13A for the 3.3V output. Following the
equation from the CURRENT LIMIT section the values for RLIM are 4.64 kΩ, 1% for the 1.2V output and 2.67 kΩ,
1% for the 3.3V output.
TRACK
Tracking for the design example is configured such that VOUT1 is controlling VOUT2. The divider values are set so
that both outputs will rise together, with VOUT2 reaching its final value just before VOUT1. Following the method in
the TRACKING section and allowing for a 120 mV offset between FB and TRK, standard 1% values are selected
for RT1 = 10 kΩ and RT2 = 35.7 kΩ.
SOFT START
To prevent over-shoot, the soft start time is set to be longer than the time it would take to charge the output
voltage at current limit. Following the equations in the STARTUP section for VOUT1 and VOUT2:
tSS1(MIN) = (3.3V x 242 μF) / (13A - 8A) = 160 μs
tSS2(MIN) = (1.2V x 462 μF) / (23A - 15A) = 69 μs
(47)
(48)
Choosing a value of CSS1 = 27 nF, the soft start time is:
tSS1 = (27 nF x 0.6V) / 8.5 μA = 1.9 ms
(49)
To ensure that VOUT2 tracks VOUT1, tSS2 is set at two-thirds of tSS1 by making CSS2 = 18 nF.
VDD, VDR and VCB CAPACITORS
VDD is used as the supply for the internal control and logic circuitry. A 1 μF ceramic capacitor provides sufficient
filtering for VDD.
24
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VDR provides power for both the high-side and low-side MOSGET gate drives, and is sized to meet the total
gate drive current. Allowing for ΔVVDR = 100 mV of ripple, the minimum value for CVDR is found from:
QG_HI + QG_LO
CVDR t
'VVDR
(50)
Using QG_HI = 15 nC and QG_LO = 30 nC with a 5V gate drive, the minimum value for CVDR = 0.45 μF.
VCB provides power for the high-side gate drive, and is sized to meet the required gate drive current. Allowing
for ΔVVCB = 100 mV of ripple, the minimum value for CBOOT is found from:
QG_HI
CBOOT t
'VVCB
(51)
To use the minimum number of different components, CVDR and CBOOT are also selected as 1 μF ceramic for the
design example.
CONTROL LOOP COMPENSATION
The LM3000 uses emulated peak current-mode PWM control to correct changes in output voltage due to line and
load transients. This unique architecture combines the fast line transient response of peak current-mode control
with the ability to regulate at very low duty cycles. In order to facilitate the use of MOSFET RDS(on) sensing, the
control ramp is set by the enable voltage and a resistor to the enable pin. This stabilizes the modulator gain from
variations in MOSFET resistance over temperature, providing a robust design solution.
The control loop is comprised of two parts. The first is the power stage, which consists of the duty cycle
modulator, output filter and load. The second part is the error amplifier, which is a transconductance amplifier
with a typical gm of 1400 μmho (or 1400 μS). Figure 29 shows the power stage and error amplifier components.
L
RL
VOUT
CO1
VIN
+
-
+
CO2
CFF
RFBT
RO
HG
RC1
PWM
LG
DRIVERS
+
Ð
+
RS = RDS(on)
A
+
RFBB
RC2
+
-
-
PGND
VSW
0.75V
gm
+
Clamped to
0.5V min
3V max
FB
RCOMP
+
-
+
-
COMP
VREF
EA_GND
CHF
CCOMP
Figure 29. Power Stage and Error Amplifier
The power stage transfer function (also called the control-to-output transfer function) in a buck converter can be
written as:
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LM3000
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vO
1+
= AVP x
vC
1+
www.ti.com
s
öZ
s
s2
+
öP x QP öP2
(52)
Where:
AVP =
Km
KD
KD = 1 +
1
Km =
(D ± 0.5) x Ri x
Km x R i
ö P x QP =
öZ =
RO
T
+ KSL
L
1
CO x RC
KD
öP2 =
L
+ CO x (Km x Ri + RC)
RO
KD
L x CO
(53)
With:
D=
VO
VIN
Ri = A x R S
T=
1
fSW
(54)
For the emulated peak current-mode control, Km is the dc modulator gain and Ri is the current-sense gain. KSL is
the proportional slope compensation, which is set by the enable resistor REN and enable voltage VEN.
Figure 30 shows a more detailed view of the current sense amplifier, which includes a three stage filter for
increased noise immunity. The effective gain and phase are shown in Figure 31 and Figure 32. The equivalent
current sense gain A = 7.
104k
11k
3.2k
-
VSW
20 pF
+
PGND
11k
3.2k
104k
15.5k
CS
AMPLIFIER
2.6 pF
SAMPLE
31k
0.75V
5.6 pF
TO RAMP
GENERATOR
Figure 30. Current Sense Amplifier and Filter
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Figure 31. Current Sense Amplifier Gain
Figure 32. Current Sense Amplifier Phase
A relatively high value of slope compensating ramp is used to stabilize the gain. This minimizes the effect of the
current sense filter on the control loop and swamps out the need for a sampling-gain term. When designing
within the recommended operating range, there is no tendency toward sub-harmonic oscillation. The proportional
slope compensation is defined as:
ISL x KSW
ISL = 8.05 éA
KSL =
IEN
fSW
KSW = 1 +
3400000
IEN =
VEN ± 0.75
REN + 2000
(55)
ISL is the internal current source scale factor, KSW is the switching frequency correction factor and IEN is the
external enable current. The recommended range for IEN is 40 μA to 160 μA. With VEN = 5V, this corresponds to
a range for REN of 25 kΩ to 100 kΩ. For operation below 4.2V input, the maximum enable current is limited, as
shown in Figure 33. At the minimum input of 3.3V, a value of 80 μA maximum corresponds to REN = 50 kΩ with
VEN = 5V. The minimum enable current is set by the enable bias circuit to ensure proper turn-on above the
threshold. A minimum enable voltage of 3V is recommended to keep the temperature coefficient of the 0.75V
internal VBE from becoming a significant error term.
Figure 33. Maximum Enable Current vs. Input Voltage
Typical frequency response of the gain and the phase for the power stage are shown in Figure 34 and Figure 35.
It is designed for VIN = 12V, VOUT = 3.3V, IOUT = 8A, VEN = 5V and a switching frequency of 500 kHz. The power
stage component values are:
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L = 2.7 μH, RL = 3.4 mΩ, CO1 = 220 μF, RC1 = 15 mΩ, CO2 = 22 μF, RC2 = 3 mΩ, RO = VOUT / IOUT = 0.41Ω, RS =
RDS(on) = 4 mΩ and REN = 43 kΩ.
Figure 34. Power Stage Gain
Figure 35. Power Stage Phase
The effective total PWM ramp height is controlled by REN. Higher REN creates a higher ramp voltage, providing
more noise immunity and less variation in the modulator gain over temperature. Lower REN requires less RC
(output capacitor ESR) for the desired phase margin and a more ideal current-mode behavior.
Figure 36 shows the transconductance amplifier network, which takes the output impedance of the amplifier and
the internal filter into account. To simplify the analysis, the 12.75 kΩ and 10 pF internal filter is absorbed into the
transconductance amplifier. This produces an equivalent REA = 15 MΩ and CBW = 22 pF for an effective 10 MHz
unity gain bandwidth.
gm
FB
VREF
+
+
-
3 pF
15M
COMPF
COMP
PWM
12.75k
4.2k
+
10 pF
5 pF
EA_GND
COMP
gm
FB
VREF
+
+
-
PWM
REA
CBW
15M
22 pF
+
-
EA_GND
Figure 36. Equivalent Transconductance Amplifier and COMP Filter
28
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Figure 37. Transconductance Amplifier Open Loop
Gain
Figure 38. Transconductance Amplifier Open Loop
Phase
Assuming a pole at the origin, the simplified equation for the error amplifier transfer function can be written in
terms of the mid-band gain as:
vC
vO
=-
AVM
KHF
öZEA
s
1+ ö
s
FZ
x
x
s
s
1+
1+
öHF
öFP
1+
(56)
Where:
AVM = KFB x gm x RCOMP
CHF + CBW
KHF = 1 +
öFZ =
CCOMP
1
CFF x RFBT
öHF =
KFB =
öZEA =
öFP =
RFBB
RFBB + RFBT
1
CCOMP x RCOMP
1
CFF x KFB x RFBT
CHF + CBW + CCOMP
(CHF + CBW) x CCOMP x RCOMP
(57)
In general, the goal of the compensation circuit is to give high dc gain, a bandwidth that is between one-fifth and
one-tenth of the switching frequency, and at least 45° of phase margin.
Control Loop Design Procedure
Once the power stage design is complete, the power stage components are used to determine the proper
frequency compensation. By equating the power stage transfer function to the error amplifier transfer function
term by term, the control loop design procedure targets an ideal single-pole system response.
The compensation components will scale from the feedback divider ratio and selection of the bottom feedback
divider resistor. A maximum value for the divider current is typically set at 1 mA. Using a divider current of 200
μA will allow for a reasonable range of values. For the bottom feedback resistor RFBB = VREF / 200 μA = 3 kΩ.
Choosing a standard 1% value of 2.94 kΩ, the top feedback resistor is found from:
RFBT = RFBB x
VOUT
VREF
-1
(58)
For VOUT = 3.3V and VREF = 0.6V, RFBT = 13.2 kΩ.
Based on the previously defined power stage values, calculate general terms:
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D=
VO
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R i = A x RS
VIN
KSW = 1 +
1
T=
fSW
RFBB
fSW
3400000
KFB =
RFBB + RFBT
(59)
For the design example D = 0.275, Ri = 0.028Ω, T = 2 μs, KSW = 1.147 and KFB = 0.1818.
Choose a target crossover frequency fC greater than the minimum control loop bandwidth from the OUTPUT
INDUCTORS section. This is typically set between 1/10 and 1/5 of the switching frequency.
öC = 2 x S x fC
öSW = 2 x S x fSW
öBW = 2 x S x fBW
(60)
Choosing fC = 100 kHz for the design example ωC = 628 krad/sec. The switching frequency ωSW = 3.14 Mrad/sec
and the error amplifier bandwidth ωBW = 62.8 Mrad/sec.
Calculate the parallel equivalent CO and RC at the target crossover frequency:
C1 = CO1
R1 = RC1
X1 =
C2 = CO2
1
öC x C1
Z=
X2 =
2
R12 + X1 x
R2 = RC2
1
öC x C2
R22 + X2
2
2
2
(R1 + R2) + (X1 + X2)
A = TAN
CO =
-1
X1
-1 X1 + X2
-1 X2
- TAN
+ TAN
R1 + R2
R1
R2
1
öC x Z x SIN(A)
RC = Z x COS(A)
(61)
For the design example X1 = 0.00723, X2 = 0.0723, Z = 0.01478 and A = 0.6304. The parallel equivalent CO =
183 μF and RC = 11.9 mΩ.
Find the optimal value of the enable current:
IEN = ISL x KSW x
L
x
CO
KFB
RC
-
1
1
-1
+ RC x
KFB
RO
Ri x 1 -
RC
RO x KFB
(62)
If IEN is not within the range of 40μA to 160μA use either the minimum or maximum limit. Find REN from:
REN =
VEN ± 0.75
IEN
- 2000
(63)
For the design example IEN = 95.5 μA and REN = 44.7 kΩ. Choosing a standard value of 43 kΩ, IEN = 94.4 μA.
Calculate other general terms:
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KSL =
ISL x KSW
1
Km =
IEN
KD = 1 +
(D ± 0.5) x Ri x T + KSL
L
Km x Ri
RO
(64)
For the design example KSL = 0.0978, Km = 10.7 and KD = 1.73.
If the enable resistor has been adjusted from the nominal value to provide more noise immunity or to meet the
minimum input voltage limit, calculate the optimal value of RC. The minimum value of RC to maintain adequate
phase margin for stability is about half this value.
RC =
KFB x L
Km x Ri x CO
(65)
Checking for the design example RC = 9.1 mΩ.
Calculate the compensation components:
gm
CBW = ö
BW
CHF =
CCOMP =
CFF =
gm x Km x RC
öC x öSW x L
KFB x gm x Km
öC x KD
RCOMP =
C O x RC
KFB x RFBT
- CBW
- (CHF + CBW)
KFB x L
KD x RC x CCOMP
(66)
For the design example, the calculated values are CBW = 22 pF, CFF = 904 pF, CHF = 11 pF, CCOMP = 2505 pF
and RCOMP = 9523Ω.
Using standard values of CFF = 820 pF, CHF = 10 pF, CCOMP = 2200 pF and RCOMP = 10 kΩ, the error amplifier
plots of gain and phase are shown in Figure 39 and Figure 40.
Figure 39. Error Amplifier Gain
Figure 40. Error Amplifier Phase
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The complete control loop transfer function is equal to the product of the power stage transfer function and error
amplifier transfer function. For the Bode plots, the overall loop gain is the equal to the sum in dB and the overall
phase is equal to the sum in degrees. Results are shown in Figure 41 and Figure 42. The crossover frequency is
100 kHz with a phase margin of 75°.
Figure 41. Control Loop Gain
Figure 42. Control Loop Phase
Compensator design for the 1.2V output is similar. With VREF = 0.6V, the feedback divider resistors are chosen
as RFBB = RFBT = 22.6 kΩ. This results in a divider current of about 25 μA, which is considered to be the
minimum acceptable level. With VEN = 5V, the nearest standard value to meet the optimal enable current is REN
= 62 kΩ. For a target crossover frequency of 100 kHz, standard values are CFF = 220 pF, CHF = 10 pF, CCOMP =
2200 pF and RCOMP = 10 kΩ.
For the small-signal analysis, it is assumed that the control voltage at the COMP pin is dc. In practice, the output
ripple voltage is amplified by the error amplifier gain at the switching frequency, which appears at the COMP pin
adding to the control ramp. This tends to reduce the modulator gain, which may lower the actual control loop
crossover frequency.
Efficiency and Thermal Considerations
The total power dissipated in the power components can be obtained by adding together the loss as mentioned
in the MOSFET, input capacitor, output capacitor and output inductor sections.
The efficiency is defined as:
POUT
K=
POUT + PTOTAL_LOSS
(67)
The highest power dissipating components are the power MOSFETs. The easiest way to determine the power
dissipated in the MOSFETs is to measure the total conversion loss (PIN - POUT), then subtract the power loss in
the capacitors, inductors and LM3000. The resulting power loss is primarily in the switching MOSFETs. Selecting
MOSFETs with exposed pads will aid the power dissipation of these devices. Careful attention to RDS(on) at high
temperature should be observed.
LM3000 OPERATING LOSS
This term accounts for the current drawn at the VIN pin, used for driving the logic circuitry and the power
MOSFETs. For the LM3000, this current is equal to the steady state operating current Iq plus the MOSFET gate
charge current IGC, which is defined as:
IGC = (QG_HI + QG_LO) x fSW
PD = VIN x (Iq + IGC)
(68)
where
•
32
PD represents the total power dissipated in the LM3000
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Iq is about 5 mA from the Electrical Characteristics table. The LM3000 has an exposed thermal pad to aid power
dissipation.
Layout Considerations
To produce an optimal power solution with a switching converter, as much care must be taken with the layout
and design of the printed circuit board as with the component selection. The following are several guidelines to
aid in creating a good layout.
KELVIN TRACES FOR GATE DRIVE AND SENSE LINES
The HG and SW pins provide the gate drive and return for the high-side MOSFET. Likewise the LG and PGND
pins provide the gate drive and return for the low-side MOSFET. These lines should run as parallel pairs to each
MOSFET, being connected as close as possible to the respective MOSFET gate and source. Although it may be
difficult in a compact design, these lines should stay away from the output inductor if possible, to avoid stray
coupling.
The EA_GND pins should also be connected with a separate Kelvin trace, running from the output ground sense
point. The sense output, which is connecting to the top of the feedback resistor divider, should also run with a
dedicated Kelvin trace together with the EA_GND. Keep these lines away from the switch node and output
inductor to avoid stray coupling. If possible, the FB and EA_GND traces should be shielded from the switch node
by ground planes. If necessary, the feedback divider impedance may be lowered to improve noise immunity.
SEPARATE PGND AND SGND
Good layout techniques include a dedicated signal ground plane, usually on an internal layer adjacent to the
LM3000 and signal component side of the board. Signal level components like the compensation and feedback
resistors should be connected to this internal plane. The SGND pin should connect directly to the DAP, with vias
from the DAP to the signal ground plane. Separate power ground plane areas for each phase should be made on
the power component side of the board, as well as other layers. This allows separate lines for each PGND pin to
connect to its respective power ground plane area at each low-side MOSFET source. The signal ground plane is
then connected to a quiet point on each power ground plane area. These connections are typically made at the
common input/output power terminals or capacitor returns. An equivalent schematic representation is shown in
the Typical Application Schematic of Figure 43.
MINIMIZE THE SWITCH NODE
The copper area that connects the power MOSFETs and output inductor together radiates more EMI as it gets
larger. Use just enough copper to give low impedance for the switching currents and provide adequate heat
spreading for the MOSFETs.
LOW IMPEDANCE POWER PATH
In a buck regulator the primary switching loop consists of the input capacitor connection to the MOSFETs.
Minimizing the area of this loop reduces the stray inductance, which minimizes noise and possible erratic
operation. The ceramic input capacitors should be placed as close as possible to the MOSFETs, with the VIN
side of the capacitors connected directly to the high-side MOSFET drain, and the PGND side of the capacitors
connected as close as possible to the low-side source. The complete power path includes the input capacitors,
power MOSFETs, output inductor, and output capacitors. Keep these components on the same side of the board
and connect them with thick traces or copper planes. Avoid connecting these components through vias whenever
possible, as vias add inductance and resistance. In general, the power components should be kept close
together, minimizing the circuit board losses.
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Typical Application
VIN
6V TO 18V
D1B
D1A
CIN1
RCBT
VDR
VOUT1
L1
3.3V, 8A
VCB1 VDR
Q1
+ COUT1
D3
RFBB1
RLIM1
Q2
VSW2
ILIM1
ILIM2
LM3000
PGND1
PGND1
GND1
VEN1
(5V)
CSS1
REN1
EN1
EN2
SS1
SS2
VDD
SGND
GND2
PGND2
RFBB2
GND2
VDD
RCOMP2
VEN2
(5V)
CSS2
REN2
TRK2
CHF2
CCOMP2
VOUT1
RT2
FREQ/
CLKOUT SYNC
RT1
CSYNC
CVDD
GND1
RPG2
PGOOD2
TRK1
PGND1
D4
PGOOD2
PGOOD1
CVDR2
Q4
CFF2
FB2
PGOOD1
VDD
CVDR1
LG2
COMP2
COMP1
RPG1
VDR
COUT2 RFBT2
+
RLIM2
PGND2
RCOMP1
CCOMP1
1.2V, 15A
EA2_GND
FB1
CHF1
VOUT2
L2
PGND2
EA1_GND
VDD
Q3
HG2
VSW1
LG1
PGND2
VIN VDD VCB2
HG1
RFBT1
CFF1
CBOOT2
CBOOT1
PGND1
CIN2
VDD
CLKOUT
RFRQ
SYNC
SGND
Figure 43. Typical Application Schematic
34
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REVISION HISTORY
Changes from Revision A (April 2013) to Revision B
•
Page
Changed layout of National Data Sheet to TI format .......................................................................................................... 34
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PACKAGE OPTION ADDENDUM
www.ti.com
8-Oct-2015
PACKAGING INFORMATION
Orderable Device
Status
(1)
LM3000SQ/NOPB
ACTIVE
Package Type Package Pins Package
Drawing
Qty
WQFN
RTV
32
1000
Eco Plan
Lead/Ball Finish
MSL Peak Temp
(2)
(6)
(3)
Green (RoHS
& no Sb/Br)
CU SN
Level-1-260C-UNLIM
Op Temp (°C)
Device Marking
(4/5)
-40 to 125
3000
(1)
The marketing status values are defined as follows:
ACTIVE: Product device recommended for new designs.
LIFEBUY: TI has announced that the device will be discontinued, and a lifetime-buy period is in effect.
NRND: Not recommended for new designs. Device is in production to support existing customers, but TI does not recommend using this part in a new design.
PREVIEW: Device has been announced but is not in production. Samples may or may not be available.
OBSOLETE: TI has discontinued the production of the device.
(2)
Eco Plan - The planned eco-friendly classification: Pb-Free (RoHS), Pb-Free (RoHS Exempt), or Green (RoHS & no Sb/Br) - please check http://www.ti.com/productcontent for the latest availability
information and additional product content details.
TBD: The Pb-Free/Green conversion plan has not been defined.
Pb-Free (RoHS): TI's terms "Lead-Free" or "Pb-Free" mean semiconductor products that are compatible with the current RoHS requirements for all 6 substances, including the requirement that
lead not exceed 0.1% by weight in homogeneous materials. Where designed to be soldered at high temperatures, TI Pb-Free products are suitable for use in specified lead-free processes.
Pb-Free (RoHS Exempt): This component has a RoHS exemption for either 1) lead-based flip-chip solder bumps used between the die and package, or 2) lead-based die adhesive used between
the die and leadframe. The component is otherwise considered Pb-Free (RoHS compatible) as defined above.
Green (RoHS & no Sb/Br): TI defines "Green" to mean Pb-Free (RoHS compatible), and free of Bromine (Br) and Antimony (Sb) based flame retardants (Br or Sb do not exceed 0.1% by weight
in homogeneous material)
(3)
MSL, Peak Temp. - The Moisture Sensitivity Level rating according to the JEDEC industry standard classifications, and peak solder temperature.
(4)
There may be additional marking, which relates to the logo, the lot trace code information, or the environmental category on the device.
(5)
Multiple Device Markings will be inside parentheses. Only one Device Marking contained in parentheses and separated by a "~" will appear on a device. If a line is indented then it is a continuation
of the previous line and the two combined represent the entire Device Marking for that device.
(6)
Lead/Ball Finish - Orderable Devices may have multiple material finish options. Finish options are separated by a vertical ruled line. Lead/Ball Finish values may wrap to two lines if the finish
value exceeds the maximum column width.
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Addendum-Page 1
Samples
PACKAGE OPTION ADDENDUM
www.ti.com
8-Oct-2015
Addendum-Page 2
PACKAGE MATERIALS INFORMATION
www.ti.com
2-Sep-2015
TAPE AND REEL INFORMATION
*All dimensions are nominal
Device
LM3000SQ/NOPB
Package Package Pins
Type Drawing
WQFN
RTV
32
SPQ
Reel
Reel
A0
Diameter Width (mm)
(mm) W1 (mm)
1000
178.0
12.4
Pack Materials-Page 1
5.3
B0
(mm)
K0
(mm)
P1
(mm)
5.3
1.3
8.0
W
Pin1
(mm) Quadrant
12.0
Q1
PACKAGE MATERIALS INFORMATION
www.ti.com
2-Sep-2015
*All dimensions are nominal
Device
Package Type
Package Drawing
Pins
SPQ
Length (mm)
Width (mm)
Height (mm)
LM3000SQ/NOPB
WQFN
RTV
32
1000
210.0
185.0
35.0
Pack Materials-Page 2
MECHANICAL DATA
RTV0032A
SQA32A (Rev B)
www.ti.com
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