Power APE2901Y5-45 Micropower vfm step-up dc/dc converter Datasheet

Advanced Power
Electronics Corp.
APE2901
MICROPOWER VFM STEP-UP DC/DC Converter
FEATURES
DESCRIPTION
Very Low Supply Current
Regulated Output Voltage
Wide Range of Output Voltage is Available from
2.5V to 5.0V by 0.1V Steps
Output Voltage Accuracy ±5%
Output Current up to 100mA
Low Ripple and Low Noise
Very Low Start-up Voltage
High Efficiency (Vout = 5V TYP. 87%)
Few External Components
Internal Soft-Start
Low Profile: SOT-23, SOT-89 & SOT-23-5L Pb-Free
The APE2901 is a high efficiency VFM Step-up DC/DC
converter for small, low input voltage or battery powered
systems with ultra low quiescent supply current. The
APE2901 accept a positive input voltage from start-up
voltage to VOUT and convert it to a higher output voltage in
the 2.5 to 5V range.
The APE2901 combine ultra low quiescent supply
current and high efficiency to give maximum battery life. The
high switching frequency and the internally limited peak
inductor current permits the use of small, low cost inductors.
Only three external components are needed an inductor a
diode and an output capacitor.
The APE2901 is suitable to be used in battery powered
equipment where low noise, low ripple and ultra low supply
current are required. The APE2901 is available in very small
package: SOT-23, SOT-89 & SOT-23-5L.
Typical applications are pagers, cameras & video
camera, cellular telephones, wireless telephones, palmtop
computer, battery backup supplies, battery powered
i
t
TYPICAL APPLICATION
VIN
VOUT
47uH
C1
100uF
NC
NC
D1
B140
SW
GND
OUT
C2
47uF
C3
1uF
APE2901
ORDERING INFORMATION
APE2901XX-XX
Package Type
Y5 : SOT-23-5L
N : SOT-23
G : SOT-89
VOUT
22 : 2.2V
25 : 2.5V
26 : 2.6V
27 : 2.7V
:
50 : 5.0V
Data and specifications subject to change without notice
1
201009076
Advanced Power
Electronics Corp.
APE2901
ABSOLUTE MAXIMUM RATINGS (TA= 25
VIN Supply Voltage(VIN) ……………………………
o
C)
5.5 V
SW Voltage(VSW ) …………………………………… 5.5 V
OUT Voltage(VOUT) …………………………………
5.5 V
Power Dissipation(PD) ……………………………… ( TJ-TA ) / Rthja W
Storage Temperature Range(T ST) ………………… -40°C To 150°C
Operating Junction Temperature Range(T OP) …… -20°C To + 100°C
Note. Rth JA is measured with the PCB copper area of approximately 1 in2(Multi-layer) that need connect to GND pin of the APE2901.
PACKAGE INFORMATION
Top View
NC
NC
5
4
SOT-89
SOT-23-5L
1
Top View
Vout
Tab is
Vout
2
1
3
2
GND Vout SW
SW GND VOUT
o
SOT-23
3
GND
o
Rthjc=110 C/W
Rthja=250oC/W
SW
o
Rthjc=100 C/W
Rthjc=110 C/W
Rthja=160oC/W
Rthja=250oC/W
ELECTRICAL SPECIFICATIONS
( VIN=1.8V, IOUT=10mA, TA=25 oC, unless otherwise specified)
Parameter
SYM
OUTPUT VOLTAGE ACCURACY
START-UP VOLTAGE(VIN-VF)(Note 1)
HOLD-ON VOLTAGE
SUPPLY CURRENT
INTERNAL SWITCH R DSON
△VOUT
MIN
TYP
MAX
UNITS
-5
-
5
%
VSTART-UP
IOUT=1mA, VIN =rising from 0 to 2V
-
0.8
1.2
V
VHOLD
IOUT=1mA, VIN =falling from 2 to 0V
0.6
-
-
V
ISUPPLY
No Load
-
22
-
uA
ILX=150mA
-
850
-
mΩ
VLX=4V, Forced VOUT=3.8V
-
-
0.5
uA
-
150
-
KHz
To be measure on SW pin
-
77
-
%
Vout=2.5V~3.0V, IOUT=50mA
-
82
-
%
Vout=3.1V~4.0V, IOUT=50mA
-
83
-
%
Vout=4.1V~5.0V, IOUT=50mA
-
87
-
%
RLX(DSON
INTERNAL LEAKAGE CURRNET
ILX(leak
MAXIMUM OSCILLATOR FREQUENCY
FOSC
OSCILLATOR DUTY ON
DON
EFFICIENCY
TEST CONDITION
η
Note 1: The minimum input voltage for the IC start-up is strictly a function of the VF catch diode.
PIN DESCRIPTIONS
PIN SYMBOL
SW
PIN DESCRIPTION
Switch Pin. Connect External Inductor & Diode here.
GND
GND Pin
OUT
Output Voltage
2
Advanced Power
Electronics Corp.
APE2901
BLOCK DIAGRAM
+
-
OUT
VREF
SW
LIMITER AMP.
- +
VFM
CONTROL
ERROR AMP.
Driver
GND
OPERATION
The APE2901 architecture is built around a VFM CONTROL logic core, switching
frequency is set through a built in oscillator. TON time is fixed (Typ. 5uS) while TOFF time
is determined by the error amplifier output, a logic signal coming from the comparison
made by the Error Amplifier Stage between the signal coming from the output voltage
divider network and the internal Band-Gap voltage reference (Vref). TOFF reaches a
minimum (Typ. 1.7uS) when heavy load conditions are met (Clock frequency 150KHz). An
over current conditions, through the internal power switch, causes a voltage drop
VLX=RDSON x ISW and the VLX limiter block forces the internal switch to be off, so narrowing
TON time and limiting internal power dissipation. In this case the switching frequency may
be higher than the 150KHz set by the internal clock generator.
VFM control ensures very low quiescent current and high conversion efficiency even
with very light loads. Since the Output Voltage pin is also used as the device Supply
Voltage, the versions with higher output voltage present an higher internal supply voltage
that results in lower power switch RDSON, slightly greater output power and higher
efficiency. Moreover, bootstrapping allows the input voltage to sag to 0.6V (at IOUT=1mA)
once the system is started. If the input voltage exceeds the output voltage, the output will
follow the input, however, the input or output voltage must not be forced above 5.5V.
APPLICATION INFORMATION
INPUT/OUTPUT CAPACITOR SELECTION
The Output Ripple Voltage, as well as the Efficiency, is strictly related to the behavior
of these elements. The output ripple voltage is the product of the peak inductor current
and the output capacitor Equivalent Series Resistance (ESR). Best performances are
obtained with good high frequency characteristics capacitors and low ESR. The best
compromise for the value of the Output Capacitance is 47µF Tantalum Capacitor; Lower
values may cause higher Output Ripple Voltage and lower Efficiency without
compromising the functionality of the device.
An Input Capacitor is required to compensate, if present, the series impedance between
the Supply Voltage Source and the Input Voltage of the Application.
INDUCTOR SELECTION
A 47µH inductor is recommended for most APE2901 applications. However, the
inductance value is not critical, and the APE2901 will work with inductors in the 33µH to
120µH.
3
Advanced Power
Electronics Corp.
APE2901
APPLICATION INFORMATION
DIODE SELECTION
Schottky diodes with higher current ratings usually have lower forward voltage drop,
larger diode capacitance and fast reverse recovery, it is the ideal choices for APE2901
applications. The forward voltage drop of a Schottky diode represents the conduction
losses in the system, while the diode capacitance (CT or CD) represents the switching
losses. For diode selection, both forward voltage drop and diode capacitance need to be
considered.
PCB LAYOUT GUIDE
When laying out the PC board, the following suggestions should be taken to ensure
proper operation of the APE2901. These items are also illustrated graphically in below.
1. The power traces, including the GND trace, the SW trace and the VCC trace should be
kept short, direct and wide to allow large current flow. Put enough multiply-layer pads
when they need to change the trace layer.
2. Do not trace signal line under inductor.
4
Advanced Power
Electronics Corp.
APE2901
TYPICAL PERFORMANCE CHARACTERISTICS
APE2901-30, IOUT=50mA, Output Voltage vs. Temperature
APE2901-30, TA=25℃ , Input Voltage vs. Output Voltage
3.05
3.50
Output Voltage (V)
2.50
0.9V
1.8V
1.2V
1.5V
2.00
1.50
1.00
Output Vlotage (V)
2.4V
3.00
3.00
2.4V
2.95
1.8V
1.2V
2.90
2.85
0.50
10
0
75
50
25
-2
0
25
0
22
5
20
0
17
5
15
0
12
5
10
0
75
50
25
10
0
0
2.80
0.00
Temperature (℃ )
Output Current (m A)
APE2901-30, Start-up Voltage vs. Output Current
APE2901-30, VIN=1.8V, Output Voltage vs. Temperature
3.10
1.0
3.00
0.9
Start-up Vlotage (V)
2.80
IOUT=50mA
IOUT=0mA
IOUT=100mA
IOUT=150mA
IOUT=200mA
IOUT=250mA
0.3
0.1
Temperature (℃ )
10
0
Output Current (mA)
APE2901-30, IOUT=1mA, Start-up Voltage vs. Temperature
APE2901-30, IOUT=1mA, Hold-On Voltage vs. Temperature
1.0
0.4
0.9
0.4
Hold-On Vlotage (V)
0.8
0.7
0.6
0.5
0.4
0.3
0.3
0.3
0.2
0.2
0.1
0.2
0.1
0.1
10
0
75
50
25
0
10
0
75
50
0
25
Temperature (℃)
-2
0
0.0
0.0
-2
0
Start-up Vlotage (V)
75
0.0
1
50
25
0
-2
0
2.30
0.4
0.2
10
0
2.40
0.5
50
2.50
0.6
25
2.60
0.7
10
2.70
75
Output Vlotage (V)
0.8
2.90
Temperature (℃ )
5
Advanced Power
Electronics Corp.
APE2901
TYPICAL PERFORMANCE CHARACTERISTICS
Input Voltage vs. Supply Current
APE2901-30, Supply Current vs. Temperature
50
800
45
700
VIN=1.2V
35
30
APE2901-33
APE2901-30
25
20
15
APE2901-28
Supply Current (uA)
600
500
400
VIN=1.5V
300
VIN=1.8V
200
10
100
5
VIN=2.4V
100
180
90
160
80
60
40
40
30
20
10
0
75
0
-2
0
0
50
10
0
25
20
-2
0
10
0
50
10
0
80
60
75
100
70
50
120
25
140
0
Oscillator Duty-On (%)
200
Temperature (℃ )
Temperature (℃ )
APE2901-30, IOUT=50mA, Efficiency vs. Temperature
APE2901-30, Efficiency vs. Output Current
90
90
80
2.4V
88
70
1.8V
86
1.2V
0.9V
1.5V
50
40
30
2.4V
1.8V
Efficiency (%)
60
84
82
80
1.2V
Output Current (mA)
75
50
25
-2
0
25
0
22
5
20
0
17
5
15
0
12
5
10
0
74
75
76
0
50
10
0
78
20
25
75
APE2901-30, Oscillator Duty-On vs. Temperature
APE2901-30, Maximum Oscillator Frequency vs. Temperature
Maximum Oscillator Frequency
(KHz)
50
Temperature (℃ )
Input Voltage (V)
Efficiency (%)
25
-2
0
2.
4
1.
8
1.
5
1.
2
0
0
0
10
0
Supply Current (uA)
40
Temperature (℃ )
6
Advanced Power
Electronics Corp.
APE2901
TYPICAL PERFORMANCE CHARACTERISTICS
APE2901-30, SW Switching Current Limit vs. Temperature
APE2901-30, VIN=1.8V, Efficiency vs. Temperature
90
900
SW Switching Current Limit (mA)
IOUT=50mA
85
IOUT=100mA
IOUT=150mA
75
IOUT=200mA
70
IOUT=250mA
65
60
55
50
860
840
820
800
780
760
Temperature (℃ )
10
0
75
50
25
0
-2
0
10
0
75
50
25
740
0
-2
0
Efficiency (%)
80
880
Temperature (℃ )
7
ADVANCED POWER ELECTRONICS CORP.
Package Outline : SOT-23-5L
Millimeters
SYMBOLS
MIN
NOM
MAX
A
1.00
1.10
1.30
A1
0.00
---
0.10
A2
0.70
0.80
0.90
b
0.35
0.40
0.50
C
0.10
0.15
0.25
D
2.70
2.90
3.10
E
1.50
1.60
1.80
e
---
1.90(TYP)
---
H
2.60
2.80
3.00
L
0.37
---
---
θ1
1°
5°
9°
e2
---
0.95(TYP)
---
Note 1:Package Body Sizes Exclude Mold Flash Protrusions or Gate Burrs.
Note 2:Tolerance ± 0.1000 mm(4mil) Unless Otherwise Spe- cified.
Note 3:Coplanarity:0.1000 mm
Note 4:Dimension L Is Measured in Gage plane.
Part Marking Information & Packing : SOT-23 -5L
Part Number : XX (Identification Code)
Date Code : YW
Y : Year W : Weak
XXYW
Part Number
Identificatio
n Code
Part Number
Identificatio
n Code
APE2901Y5-2.2V
To
APE2901Y5-3.8V
TN
APE2901Y5-2.5V
TA
APE2901Y5-3.9V
TO
APE2901Y5-2.6V
TB
APE2901Y5-4.0V
TP
APE2901Y5-2.7V
TC
APE2901Y5-4.1V
TQ
APE2901Y5-2.8V
TD
APE2901Y5-4.2V
TR
APE2901Y5-2.9V
TE
APE2901Y5-4.3V
TS
APE2901Y5-3.0V
TF
APE2901Y5-4.4V
TT
APE2901Y5-3.1V
TG
APE2901Y5-4.5V
TU
APE2901Y5-3.2V
TH
APE2901Y5-4.6V
TV
APE2901Y5-3.3V
TI
APE2901Y5-4.7V
TW
APE2901Y5-3.4V
TJ
APE2901Y5-4.8V
TX
APE2901Y5-3.5V
TK
APE2901Y5-4.9V
TY
APE2901Y5-3.6V
TL
APE2901Y5-5.0V
TZ
APE2901Y5-3.7V
TM
8
ADVANCED POWER ELECTRONICS CORP.
Package Outline : SOT-23
D
Millimeters
SYMBOLS
D1
E1
E
e
MIN
NOM
MAX
A
1.00
1.15
1.30
A1
0.00
--
0.10
A2
0.10
0.15
0.25
D1
0.30
0.40
0.50
e
1.70
2.00
2.30
D
2.70
2.90
3.10
E
2.40
2.65
3.00
E1
1.40
1.50
1.60
1.All Dimension Are In Millimeters.
A
2.Dimension Does Not Include Mold Protrusions.
A2
A1
Part Marking Information & Packing : SOT-23
XXYY
Date Code : YY
YY:2004,2008,2012…
YY:2003,2007,2011…
YY:2002,2006,2010…
YY:2001,2005,2009…
Part Number : XX (Identification Code)
Part Number
Identificatio
n Code
Part Number
Identificatio
n Code
APE2901N-2.2V
To
APE2901N-3.8V
TN
APE2901N-2.5V
TA
APE2901N-3.9V
TO
APE2901N-2.6V
TB
APE2901N-4.0V
TP
APE2901N-2.7V
TC
APE2901N-4.1V
TQ
APE2901N-2.8V
TD
APE2901N-4.2V
TR
APE2901N-2.9V
TE
APE2901N-4.3V
TS
APE2901N-3.0V
TF
APE2901N-4.4V
TT
APE2901N-3.1V
TG
APE2901N-4.5V
TU
APE2901N-3.2V
TH
APE2901N-4.6V
TV
APE2901N-3.3V
TI
APE2901N-4.7V
TW
APE2901N-3.4V
TJ
APE2901N-4.8V
TX
APE2901N-3.5V
TK
APE2901N-4.9V
TY
APE2901N-3.6V
TL
APE2901N-5.0V
TZ
APE2901N-3.7V
TM
9
ADVANCED POWER ELECTRONICS CORP.
Package Outline & Packing : SOT-89
C
J
D
B
2
1
E
3
F
I
H
K
Millimeters
SYMBOLS
MIN
NOM
MAX
A
4.40
-
4.60
B
4.05
-
4.25
C
1.40
-
1.75
E
2.40
-
2.60
F
0.89
-
1.20
I
0.35
-
0.55
H
----
1.50
----
G
----
3.00
----
J
1.40
-
1.60
K
0.35
-
0.43
G
1.All Dimensions Are in Millimeters.
A
2.Dimension Does Not Include Mold Protrusions.
Part Marking Information : SOT-89
2901&
YWWS
Part Number
Output Voltage --- APE2901-22 : o
APE2901-25 : A
APE2901-26 : B
Date Code (YWWS)
APE2901-27 : C
:
Y : Year
APE2901-49
:Y
WW:Week
APE2901-50 : Z
S:Sequence
10
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