ENPIRION EP53A8LQI-E 1000ma synchronous buck regulator with integrated inductor Datasheet

EP53A8LQI/EP53A8HQI
1000mA Synchronous Buck Regulator
with Integrated Inductor
RoHS Compliant; Halogen Free
Description
Features
The EP53A8LQI and EP53A8HQI are a 1000mA
PowerSOC. The device integrates MOSFET
switches, control, compensation, and the
Inductor in an advanced 3mm x 3mm QFN
Package.
•
Integrated Inductor Technology
•
3mm x 3mm x 1.1mm QFN package
•
Total Solution Footprint ~ 21mm2
•
Low VOUT ripple for RF compatibility
Integrated inductor ensures the complete power
solution is fully characterized with the inductor
carefully
matched
to
the
silicon
and
compensation network. . It enables a tiny solution
footprint, low output ripple, low part-count, and
high reliability, while maintaining high efficiency.
The complete solution can be implemented in as
little as 21mm2.
•
High efficiency, up to 94%
•
1000mA continuous output current
•
Less than 1µA standby current
•
5 MHz switching frequency
•
3 pin VID for glitch free voltage scaling
•
VOUT Range 0.6V to VIN – 0.5V
The EP53A8xQI uses a 3-pin VID to easily select
the output voltage setting.
Output voltage
settings are available in 2 optimized ranges
providing coverage for typical VOUT settings.
•
Short circuit and over current protection
•
UVLO and thermal protection
•
IC level reliability in a PowerSOC solution
The VID pins can be changed on the fly for fast
dynamic voltage scaling. EP53A8LQI further has
the option to use an external voltage divider.
3.5mm
4.7uF
Application
•
Portable wireless and RF applications
•
Wireless broad band data cards
•
Solid state storage applications
•
Noise and space sensitive applications
100 Ohm
100 ohm
VIN
6mm
EP53A8xQI
PVIN
VOUT
AVIN
VSENSE
ENABLE
4.7µF
0603
VFB
VS0
VOUT
10µF
0805
VS1
VS2
PGND AGND
10uF
Figure 1: Total Solution Footprint.
Figure 2: Typical Application Circuit.
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EP53A8LQI/EP53A8HQI
Ordering Information
Part Number
Comment
Package
EP53A8LQI
LOW VID Range
16-pin QFN T&R
EP53A8HQI
HIGH VID Range
16-pin QFN T&R
EP53A8LQI-E
EP53A8LQI Evaluation Board
EP53A8HQI-E
EP53A8HQI Evaluation Board
Pin Assignments (Top View)
Figure 3: EP53A8LQI Pin Out Diagram (Top View)
PIN
NAME
1, 15,
16
NC(SW)
2,3
PGND
4
VFB
5
VSENSE
6
AGND
7, 8
VOUT
9, 10,
11
VS2, VS1,
VS0
12
13
14
ENABLE
AVIN
PVIN
FUNCTION
NO CONNECT – These pins are internally connected to the common switching node of the
internal MOSFETs. NC (SW) pins are not to be electrically connected to any external signal,
ground, or voltage. However, they must be soldered to the PCB. Failure to follow this
guideline may result in part malfunction or damage to the device.
Power ground. Connect this pin to the ground electrode of the Input and output filter
capacitors.
EP53A8LQI: Feed back pin for external divider option.
EP53A8HQI: No Connect
Sense pin for preset output voltages. Refer to application section for proper configuration.
Analog ground. This is the quiet ground for the internal control circuitry, and the ground
return for external feedback voltage divider
Regulated Output Voltage. Refer to application section for proper layout and decoupling.
Output voltage select. VS2 = pin 9, VS1 = pin 10, VS0 = pin 11.
EP53A8LQI: Selects one of seven preset output voltages or an external resistor divider.
EP53A8HQI: Selects one of eight preset output voltages.
(Refer to section on output voltage select for more details.)
Output Enable. Enable = logic high; Disable = logic low
Input power supply for the controller circuitry. Connect to PVIN through a 100 Ohm resistor.
Input Voltage for the MOSFET switches.
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03651
Figure 4: EP53A8HQI Pin Out Diagram (Top View)Pin
Description
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EP53A8LQI/EP53A8HQI
Absolute Maximum Ratings
CAUTION: Absolute Maximum ratings are stress ratings only. Functional operation beyond the
recommended operating conditions is not implied. Stress beyond the absolute maximum ratings may
cause permanent damage to the device. Exposure to absolute maximum rated conditions for
extended periods may affect device reliability.
PARAMETER
SYMBOL
MIN
MAX
UNITS
VIN
-0.3
6.0
V
Voltages on: ENABLE, VSENSE, VSO – VS2
-0.3
VIN+ 0.3
V
Voltages on: VFB (EP53A8LQI)
-0.3
2.7
V
150
°C
150
°C
Reflow Temp, 10 Sec, MSL3 JEDEC J-STD-020C
260
°C
ESD Rating (based on Human Body Mode)
2000
V
Input Supply Voltage
Maximum Operating Junction Temperature
TJ-ABS
Storage Temperature Range
TSTG
-65
Recommended Operating Conditions
PARAMETER
SYMBOL
MIN
MAX
UNITS
Input Voltage Range
VIN
2.4
5.5
V
Operating Ambient Temperature
TA
- 40
+85
°C
Operating Junction Temperature
TJ
- 40
+125
°C
Thermal Characteristics
PARAMETER
Thermal Resistance: Junction to Ambient –0 LFM (Note 1)
Thermal Overload Trip Point
Thermal Overload Trip Point Hysteresis
SYMBOL
TYP
UNITS
θJA
85
°C/W
TJ-TP
+155
°C
25
°C
Note 1: Based on a four layer copper board and proper thermal design per JEDEC EIJ/JESD51 standards
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EP53A8LQI/EP53A8HQI
Electrical Characteristics
NOTE: TA = -40°C to +85°C unless otherwise noted. Typical values are at TA = 25°C, VIN = 3.6V.
CIN = -4.7µF 0603 MLCC, COUT = 10µF 0805 MLCC
PARAMETER
SYMBOL
Operating Input Voltage
VIN
Under Voltage Lock-out –
VIN Rising
VUVLO_R
2.0
V
Under Voltage Lock-out –
VIN Falling
VUVLO_F
1.9
V
Drop Out Resistance
RDO
Input to Output Resistance
Output Voltage Range
VOUT
EP53A8LQI (VDO = ILOAD X RDO)
EP53A8HQI
Dynamic Voltage Slew
Rate
VSLEW
EP53A8HQI
EP53A8LQI
∆VOUT
TA = 25°C, VIN = 3.6V;
ILOAD = 100mA ;
0.8V ≤ VOUT ≤ 3.3V
-2
Feedback Pin Voltage
Initial Accuracy
VFB
TA = 25°C, VIN = 3.6V;
ILOAD = 100mA ;
0.8V ≤ VOUT ≤ 3.3V
.588
Line Regulation
∆VOUT_LINE
2.4V ≤ VIN ≤ 5.5V
0.03
%/V
Load Regulation
∆VOUT_LOAD
0A ≤ ILOAD ≤ 1000mA
0.6
%/A
Temperature Variation
∆VOUT_TEMPL
-40°C ≤ TA ≤ +85°C
30
ppm/°C
Output Current
IOUT
Shut-down Current
ISD
Enable = Low
OCP Threshold
ILIM
2.4V ≤ VIN ≤ 5.5V
0.6V ≤ VOUT ≤ 3.3V
VS0-VS2, Pin Logic Low
VVSLO
0.0
0.3
V
VS0-VS2, Pin Logic High
VVSHI
1.4
VIN
V
VS0-VS2, Pin Input
Current
IVSX
Enable Pin Logic Low
VENLO
Enable Pin Logic High
VENHI
Enable Pin Current
IENABLE
Note 1
<100
nA
Feedback Pin Input
Current
IFB
Note 1
<100
nA
Operating Frequency
FOSC
5
MHz
8
4
V/mS
VID Preset VOUT Initial
Accuracy
TEST CONDITIONS
MIN
TYP
2.4
350
0.6
1.8
MAX
UNITS
5.5
V
500
VIN-VDO
3.3
8
4
Note 1
V
V/mS
0.6
+2
%
0.612
V
1000
1.25
mΩ
mA
0.75
µA
1.4
A
<100
nA
0.3
1.4
V
V
Soft Start Operation
Soft Start Slew Rate
∆VSS
EP53A8HQI (VID only)
EP53A8LQI (VID only)
Soft Start Rise Time
∆TSS
EP53A8LQI (VFB mode); Note 2
170
225
280
µS
Note 1: Parameter guaranteed by design and characterization.
Note 2: Measured from when VIN ≥ VUVLO_R & ENABLE pin crosses its logic High threshold.
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EP53A8LQI/EP53A8HQI
95
95
85
85
75
75
Efficiency (%)
Efficiency (%)
Typical Performance Characteristics
65
55
65
55
45
45
35
35
25
25
0
100
200
300
400
500
600
700
800
900 1000
0
Load Current (A)
100
200
300
400
500
600
700
800
900
1000
Load Current (A)
Efficiency vs. Load Current: VIN = 5.0V, VOUT (from
top to bottom) = 3.7, 3.3, 2.5, 1.8, 1.2V
Efficiency vs. Load Current: VIN = 3.3V, VOUT (from
top to bottom) = 2.5, 1.8V,1.2V
Start Up Waveform: VIN = 5.0V, VOUT = 3.3V; ILOAD =
1000mA
Shut-down Waveform: VIN = 5.0V, VOUT = 3.3V; ILOAD =
1000mA
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EP53A8LQI/EP53A8HQI
5mV/Div
Output Ripple: VIN = 5.0V, VOUT = 1.2V, Load = 1A
5mV/Div
Output Ripple: VIN = 5.0V, VOUT = 3.3V, Load = 1A
5mV/Div
5mV/Div
Output Ripple: VIN = 3.3V, VOUT = 1.8V, Load = 1A
Output Ripple: VIN = 3.3V, VOUT = 1.2V, Load = 1A
Load Transient: VIN = 5.0V, VOUT = 3.3V
Load stepped from 0mA to 1000mA
Load Transient: VIN = 5.0V, VOUT = 1.2V
Load stepped from 0mA to 1000mA
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EP53A8LQI/EP53A8HQI
Load Transient: VIN = 3.7V, VOUT = 1.2V
Load stepped from 0mA to 1000mA
Load Transient: VIN = 3.3V, VOUT = 1.8V
Load stepped from 0mA to 1000mA
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EP53A8LQI/EP53A8HQI
Functional Block Diagram
PVIN
UVLO
Thermal Limit
Current Limit
ENABLE
NC(SW)
Soft Start
P-Drive
(-)
Logic
VOUT
PWM
Comp
(+)
N-Drive
PGND
VSENSE
Sawtooth
Generator
Compensation
Network
(-)
Switch
VFB
Error
Amp
(+)
DAC
Voltage
Select
VREF
Package Boundry
AVIN
VS0 VS1 VS2
AGND
Figure 5: Functional Block Diagram
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EP53A8LQI/EP53A8HQI
Detailed Description
Functional Overview
The EP53A8xQI requires only 2 small MLCC
capacitors and an 0201MLC resistor for a
complete DC-DC converter solution.
The
device integrates MOSFET switches, PWM
controller, Gate-drive, compensation, and
inductor into a tiny 3mm x 3mm x 1.1mm QFN
package. Advanced package design, along
with the high level of integration, provides very
low output ripple and noise. The EP53A8xQI
uses voltage mode control for high noise
immunity and load matching to advanced
≤90nm loads. A 3-pin VID allows the user to
choose from one of 8 output voltage settings.
The EP53A8xQI comes with two VID output
voltage ranges. The EP53A8HQI provides
VOUT settings from 1.8V to 3.3V, the
EP53A8LQI provides VID settings from 0.8V to
1.5V, and also has an external resistor divider
option to program output setting over the 0.6V
to VIN-0.5V range. The EP53A8xQI provides
the industry’s highest power density of any 1A
DCDC converter solution.
The key enabler of this revolutionary
integration is Enpirion’s proprietary power
MOSFET technology. The advanced MOSFET
switches are implemented in deep-submicron
CMOS to supply very low switching loss at high
switching frequencies and to allow a high level
of integration. The semiconductor process
allows seamless integration of all switching,
control, and compensation circuitry.
The proprietary magnetics design provides
high-density/high-value magnetics in a very
small footprint.
Enpirion magnetics are
carefully matched to the control and
compensation circuitry yielding an optimal
solution with assured performance over the
entire operating range.
Protection features include under-voltage lockout (UVLO), over-current protection (OCP),
short circuit protection, and thermal overload
protection.
Integrated Inductor: Low-Noise Low-EMI
The EP53A8xQI utilizes a proprietary low loss
integrated inductor. The integration of the
©Enpirion 2009 all rights reserved, E&OE
03651
inductor greatly simplifies the power supply
design process. The inherent shielding and
compact construction of the integrated inductor
reduces the conducted and radiated noise that
can couple into the traces of the printed circuit
board.
Further, the package layout is
optimized to reduce the electrical path length
for the high di/dT input AC ripple currents that
are a major source of radiated emissions from
DC-DC converters. The integrated inductor
provides the optimal solution to the complexity,
output ripple, and noise that plague low power
DCDC converter design.
Voltage Mode Control, High Bandwidth
The EP53A8xQI utilizes an integrated type III
compensation network. Voltage mode control
is inherently impedance matched to the sub
90nm process technology that is used in
today’s advanced ICs. Voltage mode control
also provides a high degree of noise immunity
at light load currents so that low ripple and high
accuracy are maintained over the entire load
range. The very high switching frequency
allows for a very wide control loop bandwidth
and hence excellent transient performance.
Soft Start
Internal soft start circuits limit in-rush current
when the device starts up from a power down
condition or when the “ENABLE” pin is
asserted “high”. Digital control circuitry limits
the VOUT ramp rate to levels that are safe for
the Power MOSFETS and the integrated
inductor.
The EP53A8HQI has a soft-start slew rate that
is twice that of the EP53A8LQI.
When the EP53A8LQI is configured in external
resistor divider mode, the device has a fixed
VOUT ramp time. Therefore, the ramp rate will
vary with the output voltage setting. Output
voltage ramp time is given in the Electrical
Characteristics Table.
Excess bulk capacitance on the output of the
device can cause an over-current condition at
startup. Assuming no-load at startup, the
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EP53A8LQI/EP53A8HQI
maximum total capacitance on the output,
including the output filter capacitor and bulk
and decoupling capacitance, at the load, is
given as:
EP53A8LQI:
COUT_TOTAL_MAX = COUT_Filter + COUT_BULK = 250uF
Under Voltage Lockout
During initial power up, an under voltage
lockout circuit will hold-off the switching
circuitry until the input voltage reaches a
sufficient level to insure proper operation. If
EP53A8HQI:
the lockout circuitry will again disable the
switching. Hysteresis is included to prevent
chattering between states.
COUT_TOTAL_MAX = COUT_Filter + COUT_BULK = 125uF
Enable
EP53A8LQI (in external divider mode):
COUT_TOTAL_MAX = 2.25x10-4/VOUT Farads
The nominal value for COUT is 10uF. See the
applications section for more details.
Over Current/Short Circuit Protection
The current limit function is achieved by
sensing the current flowing through a sense PMOSFET which is compared to a reference
current. When this level is exceeded the PFET is turned off and the N-FET is turned on,
pulling VOUT low. This condition is maintained
for approximately 0.5mS and then a normal
soft start is initiated. If the over current
condition still persists, this cycle will repeat.
The ENABLE pin provides a means to shut
down the converter or enable normal
operation.
A logic low will disable the
converter and cause it to shut down. A logic
high will enable the converter into normal
operation.
NOTE: The ENABLE pin must not be left
floating.
Thermal Shutdown
When excessive power is dissipated in the
chip, the junction temperature rises. Once the
junction temperature exceeds the thermal
shutdown temperature, the thermal shutdown
circuit turns off the converter output voltage
thus allowing the device to cool. When the
junction temperature decreases by 25C°, the
device will go through the normal startup
process.
Application Information
100 ohm
VIN
PVIN
VOUT
AVIN
VSENSE
ENABLE
4.7µF
0603
VS0
100 ohm
VOUT
VIN
4.7µF
0603
VSENSE
VFB
VS0
VS2
10µF
0805
PGND AGND
Figure 7: Application Circuit, EP53A8LQI showing
the VFB function.
Figure 6: Application Circuit, EP53A8HQI.
03651
AVIN
VOUT
VS1
PGND AGND
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VOUT
ENABLE
10µF
0805
VS1
VS2
PVIN
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EP53A8LQI/EP53A8HQI
Output Voltage Programming
The EP53A8xQI utilizes a 3-pin VID to program
the output voltage value. The VID is available
in two sets of output VID programming ranges.
The VID pins should be connected either to an
external control signal, AVIN or to AGND to
avoid noise coupling into the device.
The “Low” range is optimized for low voltage
applications. It comes with preset VID settings
ranging from 0.80V and 1.5V. This VID set
also has an external divider option.
To specify this VID range, order part number
EP53A8LQI.
The “High” VID set provides output voltage
settings ranging from 1.8V to 3.3V. This
version does not have an external divider
option. To specify this VID range, order part
number EP53A8HQI.
Internally, the output of the VID multiplexer
sets the value for the voltage reference DAC,
which in turn is connected to the non-inverting
input of the error amplifier. This allows the use
of a single feedback divider with constant loop
gain and optimum compensation, independent
of the output voltage selected.
voltage divider option. The VID pin settings
can be changed on the fly to implement glitchfree voltage scaling.
Table 1 shows the VS2-VS0 pin logic states for
the EP53A8LQI and the associated output
voltage levels.
A logic “1” indicates a
connection to AVIN or to a “high” logic voltage
level. A logic “0” indicates a connection to
AGND or to a “low” logic voltage level. These
pins can be either hardwired to AVIN or AGND
or alternatively can be driven by standard logic
levels. Logic levels are defined in the electrical
characteristics table. Any level between the
logic high and logic low is indeterminate.
EP53A8LQI External Voltage Divider
The external divider option is chosen by
connecting VID pins VS2-VS0 to VIN or a logic
“1” or “high”. The EP53A8LQI uses a separate
feedback pin, VFB, when using the external
divider. VSENSE must be connected to VOUT as
indicated in Figure 8.
The output voltage is selected by the following
formula:
)
VOUT = 0.6V (1 + Ra
Rb
100 Ohms
VIN
4.7uF
0603
Table 1: EP53A8LQI VID Voltage Select Settings
VS2
0
0
0
0
1
1
1
1
VS1
0
0
1
1
0
0
1
1
VS0
0
1
0
1
0
1
0
1
VOUT
1.50
1.45
1.20
1.15
1.10
1.05
0.8
EXT
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03651
VSense
AVIN
ENABLE
VS0
VS1
VS2
VOUT
VOUT
Ra
10µF
0805
VFB
Rb
PGND AGND
Figure 8: EP53A8LQI using external divider
Ra must be chosen as 237KΩ to maintain loop
gain. Then Rb is given as:
EP53A8L Low VID Range Programming
The EP53A8LQI is designed to provide a high
degree of flexibility in powering applications
that require low VOUT settings and dynamic
voltage scaling (DVS). The device employs a
3-pin VID architecture that allows the user to
choose one of seven (7) preset output voltage
settings, or the user can select an external
PVIN
EP53A8L
NOTE: The VID pins must not be left floating.
R
b
=
142.2 x10 3
Ω
VOUT − 0.6
VOUT can be programmed over the range of
0.6V to (VIN – 0.5V).
NOTE: Dynamic Voltage Scaling is not allowed
between internal preset voltages and external
divider.
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EP53A8LQI/EP53A8HQI
EP53A8HQI High VID Range
Programming
The EP53A8HQI VOUT settings are optimized
for higher nominal voltages such as those
required to power IO, RF, or IC memory. The
preset voltages range from 1.8V to 3.3V.
There are eight (8) preset output voltage
settings. The EP53A8HQI does not have an
external divider option.
As with the
EP53A8LQI, the VID pin settings can be
changed while the device is enabled.
Table 2 shows the VS0-VS2 pin logic states for
the EP53A8HQI and the associated output
voltage levels.
A logic “1” indicates a
connection to AVIN or to a “high” logic voltage
level. A logic “0” indicates a connection to
AGND or to a “low” logic voltage level. These
pins can be either hardwired to AVIN or AGND
or alternatively can be driven by standard logic
levels. Logic levels are defined in the electrical
characteristics table. Any level between the
logic high and logic low is indeterminate.
These pins must not be left floating.
Table 2: EP53A8HQI VID Voltage Select Settings
VS2
0
0
0
0
1
1
1
1
VS1
0
0
1
1
0
0
1
1
VS0
0
1
0
1
0
1
0
1
VOUT
3.3
3.0
2.9
2.6
2.5
2.2
2.1
1.8
Input Filter Capacitor
The input filter capacitor requirement is a
4.7µF 0603 low ESR MLCC capacitor. The
©Enpirion 2009 all rights reserved, E&OE
03651
input capacitor must use a X5R or X7R or
equivalent dielectric formulation.
Y5V or
equivalent
dielectric
formulations
lose
capacitance with frequency, bias, and with
temperature, and are not suitable for switchmode DC-DC converter input filter applications.
Output Filter Capacitor
The output filter capacitor requirement is a
minimum of 10µF 0805 MLCC.
Ripple
performance can be improved by using 2x10µF
0603 or 2x10µF 0805 MLCC capacitors.
The maximum output filter capacitance next to
the output pins of the device is 60µF low ESR
MLCC capacitance. VOUT has to be sensed at
the last output filter capacitor next to the
EP53A8xQI.
Additional bulk capacitance for decoupling and
bypass can be placed at the load as long as
there is sufficient separation between the VOUT
Sense point and the bulk capacitance. The
separation provides an inductance that isolates
the control loop from the bulk capacitance.
Excess total capacitance on the output (Output
Filter + Bulk) can cause an over-current
condition at startup. Refer to the section on
Soft-Start for the maximum total capacitance
on the output.
The output capacitor must use a X5R or X7R or
equivalent dielectric formulation.
Y5V or
equivalent
dielectric
formulations
lose
capacitance with frequency, bias, and
temperature and are not suitable for switch-mode
DC-DC converter output filter applications.
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EP53A8LQI/EP53A8HQI
Recommended PCB Footprint
Figure 9: EP53A8xQI Package PCB Footprint
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EP53A8LQI/EP53A8HQI
Package and Mechanical
Figure 10: EP53A8xQI Package Dimensions
Contact Information
Enpirion, Inc.
Perryville III
53 Frontage Road Suite 210
Hampton, NJ 08827
Tel..908.894.6000
Fax: 908-894-6090
Enpirion reserves the right to make changes in circuit design and/or specifications at any time without notice. Information furnished by Enpirion is
believed to be accurate and reliable. Enpirion assumes no responsibility for its use or for infringement of patents or other third party rights, which may
result from its use. Enpirion products are not authorized for use in nuclear control systems, as critical components in life support systems or equipment
used in hazardous environment without the express written authority from Enpirion.
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