MICREL MIC2142

MIC2142
Micropower Boost Converter
General Description
Features
The MIC2142 is a micropower boost switching regulator
• 2.2V to 16V input voltage
housed in a SOT23-5 package. The input voltage range is
• Up to 22V output voltage
between 2.2V to 16V, making the device suitable for one• 330kHz switching frequency
cell Li Ion and 3 to 4-cell alkaline/NiCad/NiMH applica• 0.1µA shutdown current
tions. The output voltage of the MIC2142 can be adjusted
• 85µA quiescent current
up to 22V.
• Implements low-power boost, SEPIC, or flyback
The MIC2142 is well suited for portable, space-sensitive
applications. It features a low quiescent current of 85µA,
• SOT23-5 package
and a typical shutdown current of 0.1µA. It’s 330kHz
operation allows small surface mount external components
Applications
to be used. The MIC2142 is capable of efficiencies over
85% in a small board area.
• LCD bias supply
The MIC2142 can be configured to efficiently power a
• White LED driver
variety of loads. It is capable of providing a few mA output
• 12V Flash memory supply
for supplying low power bias voltages; it is also capable of
• Local 3V to 5V conversion
providing the 80mA needed to drive 4 white LEDs.
The MIC2142 is available in a SOT23-5 package with an
ambient operating temperature range from –40°C to
+85°C.
Data sheets and support documentation can be found on
Micrel’s web site at www.micrel.com.
___________________________________________________________________________________________________________
Typical Application
1
CIN
10µF
5
D1
MIC2142
VCC SW
3
FB
4
EN GND
2
Typical Configuration
+5V @60mA
R2
365k
R1
124k
COUT
22µF
EFFICIENCY (%)
L1
33µH
2.8V to 4.7V
VIN
0.90
0.85
0.80
0.75
0.70
0.65
0.60
0.55
0.50
0.45
0.40
0
Efficiency
vs. Output Current
VIN = 4.2V
VIN = 3.0V
10 20 30 40 50 60 70
OUTPUT CURRENT (mA)
Efficiency vs. Output Current
Micrel Inc. • 2180 Fortune Drive • San Jose, CA 95131 • USA • tel +1 (408) 944-0800 • fax + 1 (408) 474-1000 • http://www.micrel.com
October 2007
M9999-102507
Micrel, Inc.
MIC2142
Ordering Information
Part Number
Marking*
Standard
Pb-Free
Standard
Pb-Free
MIC2142BM5
MIC2142YM5
SBAA
SBAA
Voltage
Ambient
Temperature Range
Package
Adj.
–40° to +85°C
5-Pin SOT23
* Under bar symbol (_) may not be to scale.
Pin Configuration
5-Pin SOT23 (BM5)
5-Pin SOT23 (YM5)
Pin Description
Pin Number
Pin Name
Pin Function
1
VCC
Chip Supply: +2.2V to +16V.
2
GND
Ground: Return for internal circuitry and internal MOSFET (switch) source.
3
SW
Switch Node (Input): Internal MOSFET drain; 22V maximum.
4
FB
Feedback (Input): Output voltage sense node.
5
EN
Shutdown: Device shuts down to 0.1µA typical supply current.
October 2007
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M9999-102507
Micrel, Inc.
MIC2142
Absolute Maximum Ratings(1)
Operating Ratings(2)
Supply Voltage (VCC)......................................................18V
Switch Voltage (VSW)......................................................24V
Enable Pin Voltage (VEN)(3) .............................................18V
Feedback Voltage (VFB)
Adjustable Version.....................................................8V
Ambient Storage Temperature (Ts) ...........–65°C to +150°C
ESD Rating(4)
Supply Voltage (VCC)......................................... 2.2V to 16V
Enable Pin Voltage (VEN)(3)................................... 0V to 16V
Switch Voltage (VSW)......................................................22V
Ambient Temperature (TA) .......................... –40°C to +85°C
Junction Temperature Range (TJ)............. –40°C to +125°C
Package Thermal Impedance
SOT23-5 (θJA) ..................................................220°C/W
Electrical Characteristics
VCC = 3.6V; VOUT = 5V; IOUT = 200mA; TA = 25°C, bold values indicate –40°C< TJ < +125°C, unless noted.
Parameter
Condition
Min
Input Voltage
Quiescent Current
Feedback Voltage (VFB)
2.2
Enable Input Voltage
Max
Units
16
V
µA
VEN = ON , VFB = 2.2V (adjustable)
85
125
VEN = ON , VOUT(NOMINAL) + 1V (MIC2142-5.0)
85
125
µA
VEN = OFF (shutdown)
0.1
2
µA
1.28
1.306
V
(±2%)
1.254
(±3%)
1.241
Comparator Hysteresis
Feedback Input Bias Current,
Note 5
Typ
adjustable
fixed
VIH (turn on)
0.6VCC
VIL (turn off)
Enable Input Current
–1
1.312
V
18
mV
30
nA
20
µA
0.55VCC
V
1.1
0.8
V
0.01
1
µA
Load Regulation
200µA ≤ IOUT ≤ 20mA
0.2
%VOUT
Line Regulation
2.2V ≤ VCC ≤ 16V; IOUT = 4mA (adjustable)
0.25
%/V
2.2V ≤ VCC ≤ 4.5V; IOUT = 4mA (MIC2142-5.0)
0.25
%/V
SW on Resistance
ISW = 100mA, VCC = 2.5V
Switch Leakage Current
VEN = OFF, VSW = 12V
5
Ω
0.05
1
µA
Oscillator Frequency
295
330
365
kHz
Duty Cycle
50
57
65
%
Notes:
1. Absolute maximum ratings indicate limits beyond which damage to the component may occur. Electrical specifications do not apply when operating
the device outside of its operating ratings. The maximum allowable power dissipation is a function of the maximum junction temperature, TJ(Max), the
junction-to-ambient thermal resistance, θJA, and the ambient temperature, TA. The maximum allowable power dissipation will result in excessive die
temperature, and the regulator will go into thermal shutdown. The θJA of the power SOT23-5 is 220°C/W mounted on a PC board.
2. The device is not guaranteed to function outside its operating rating.
3. VEN must be ≤ VIN.
4. Devices are ESD sensitive. Handling precautions recommended.
5. The maximum suggested value of the programming resistor, whose series resistance is measured from feedback to ground, is 124kΩ. Use of larger
resistor values can cause errors in the output voltage due to the feedback input bias current.
October 2007
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M9999-102507
Micrel, Inc.
MIC2142
Typical Characteristics
Quiescent Current
vs. Input Voltage
250
200
150
100
50
2
IL = 2mA
L = 220µH
200
Oscillator Characteristics
vs. Input Voltage
Frequency
250
0.65
0.60
0.55
200
Duty Cycle
0.50
100 V = 15V
O
0.45
50 IO = 100µA
L= 220µH
0
0.40
0
2
4 6 8 10 12 14
INPUT VOLTAGE (V)
84
14
MIC2142 Load
Regulation
VOUT
14
12
10
L = 22µH
8 VIN = 5V
6
4
VREF
2
5
10 15 20 25 30
OUTPUT CURRENT (mA)
Quiescent Current
vs. Temperature
80
78
76
74
72
VIN = 3.6V
70
-50 -30 -10 10 30 50 70 90 110
TEMPERATURE °C)
(
Frequency vs.
Temperature
335
FREQUENCY (kHz)
6
8
10 12
INPUT VOLTAGE (V)
82
340
330
325
320
315
310
305
300
295
-50 -30 -10 10 30 50 70 90 110
TEMPERATURE °C)
(
October 2007
4
0
0
4
6 8 10 12 14
INPUT VOLTAGE (V)
QUIESCENT CURRENT (µA)
2
DUTY CYCLE
0
0
150
14.5
OUTPUT VOLTAGE (V)
400
300
15
16
800
VOUT = 15V
IL = 2mA
L = 220µH
14
2
IL = 7mA
L = 22 H
600
Line Regulation
IL = 7mA
L = 22 H
15.5
Output Ripple
vs. Input Voltage
1000
350
16
4 6 8 10 12 14 16
INPUT VOLTAGE (V)
1200
OUTPUT RIPPLE (mV)
OUTPUT VOLTAGE (V)
VOUT = 5V
300
0
0
FREQUENCY (kHz)
16.5
4
OSCILLATOR CHARACTERISTICS
QUIESCENT CURENT (µA)
350
3.5
Timing Characteristics
Over Temperature
3.0 T (µsec)
2.5
2.0
1.5 t
ON
(µsec)
1.0
0.5
Duty Cycle
0
-50 -30 -10 10 30 50 70 90 110
TEMPERATURE °C)
(
M9999-102507
Micrel, Inc.
MIC2142
Typical Characteristics (cont.)
6
VCC=3.3V
RDS(O N) (Ω)
5
4
3
VCC = 4.5V
2
1
0
-50 -30 -10 10 30 50 70 90 110
TEMPERATURE °C)
(
October 2007
DUTY CYCLE (%)
7
Timing Characteristics
Over Temperature
RDS(ON) vs.
Temperature
0.6
0.58
0.56
0.54
0.52
0.5
0.48
0.46
0.44
0.42
0.4
-50 -30 -10 10 30 50 70 90 110
TEMPERATURE °C)
(
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M9999-102507
Micrel, Inc.
MIC2142
Functional Diagram
SW
VCC
Bandgap
Reference
1.265V
Oscillator
330kHz
FIXED DUTY CYCLE
EN
Shutdown
FB
MIC2142
GND
Functional Description
This MIC2142 is a fixed duty cycle, constant frequency,
gated oscillator, micropower, switch-mode power supply
controller. Quiescent current for the MIC2142 is only
85µA in the switch off state, and since a MOSFET output
switch is used, additional switch drive current is
minimized. Efficiencies above 85% throughout most
operating conditions can be realized.
A functional block diagram is shown above and typical
schematic is shown on page 1. Regulation is performed
by a hysteretic comparator, which regulates the output
voltage by gating the internal oscillator. The internal
oscillator operates at a fixed 57% duty cycle and 330kHz
frequency. For the fixed output versions, the output is
divided down internally and then compared to the
internal VREF input. An external resistive divider is use for
the adjustable version.
October 2007
The comparator has hysteresis built into it, which
determines the amount of low frequency ripple that will
be present on the output. Once the feedback input to the
comparator exceeds the control voltage by 18mV, the
high frequency oscillator drive is removed from the
output switch. As the feedback input to the comparator
returns to the reference voltage level, the comparator is
reset and the high frequency oscillator is again gated to
the output switch. The 18mV of hysteresis seen at the
comparator will be multiplied by the ratio of the output
voltage to the reference voltage. For a five volt output
this ratio would be 4, corresponding to a ripple voltage of
72mV at the output.
The maximum output voltage is limited by the voltage
capability of the output switch. Output voltages up to 22V
can be achieved with a standard boost circuit. Higher
output voltages can be realized with a flyback
configuration.
6
M9999-102507
Micrel, Inc.
MIC2142
Application Information
Pre-designed circuit information is at the end of this
section.
Component Selection
Resistive Divider (Adjustable Version)
The external resistive divider should divide the output
volt-age down to the nominal reference voltage. Current
drawn through this resistor string should be limited in
order to limit the effect on the overall efficiency. The
maximum value of the resistor string is limited by the
feedback input bias current and the potential for noise
being coupled into the feedback pin. A resistor string on
the order of 2MΩ limits the additional load on the output
to 20µA for a 20V output. In addition, the feedback input
bias current error would add a nominal 60mV error to the
expected output. Equation 1 can be used for determining
the values for R2 and R1.
(1)
VOUT
IO(max) =
(3)
IPK =
(VIN(min) t ON ) 2
2L MAX TS
×
1
VO
− VIN(min)
eff
t ON(max)VIN(max)
L MIN
Table 1 lists common inductors suitable for most
applications. Due to the internal transistor peak current
limitation at low input voltages, inductor values less than
10µH are not recommended. Table 6 lists minimum
inductor sizes versus input and output voltage. In lowcost, low-peak-current applications, RF-type leaded
inductors may sufficient. All inductors listed in Table 5
can be found within the selection of CR32- or LQH4Cseries inductors from either Sumida or MuRata.
⎛ R1 + R2 ⎞
=⎜
⎟ VREF
⎝ R1 ⎠
Boost Inductor
Maximum power is delivered to the load when the
oscillator is gated on 100% of the time. Total output
power and circuit efficiency must be considered when
determining the maximum inductor value. The largest
inductor possible is preferable in order to minimize the
peak current and output ripple. Efficiency can vary from
80% to 90% depending upon input voltage, output
voltage, load current, inductor, and output diode.
Equation 2 solves for the output current capability for a
given inductor value and expected efficiency. Figures 7
through 12 show estimates for maximum output current
assuming the minimum duty and maximum frequency
and 80% efficiency. To determine the necessary
inductance; find the intersection between the output
voltage and current, and then select the value of the
inductor curve just above the intersection. If the
efficiency is expected to be different than the 85% used
for the graph, Equation 2 can then be used to better
determine the maximum output capability.
The peak inductor/switch current can be calculated from
Equation 3 or read from the graph in Figure 13. The
peak current shown in the graph in Figure 13 is derived
assuming a max duty cycle and a minimum frequency.
The selected inductor and diode peak current capability
must be greater than this. The peak current seen by the
inductor is calculated at the maximum input voltage. A
wide ranging input voltage will result in a higher worst
case peak current in the inductor than a narrow input
range.
October 2007
(2)
Manufacturer
Series
Device Type
MuRata
LC4/C3/C1HQ
surface mount
Sumida
CR32
surface mount
J.W. Miller
78F
axial leaded
Coilcraft
90
axial leaded
Table 1. Inductor Examples
Boost Output Diode
Speed, forward voltage, and reverse current are very
important in selecting the output diode. In the boost
configuration the average diode current is the same as
the average load current and the peak is the same as
the inductor and switch current. The peak current is the
same as the peak inductor current and can be derived
from Equation 3 or the graph in Figure 13. Care must be
taken to make sure that the peak current is evaluated at
the maximum input voltage.
The BAT54 and BAT85 series are low current Shottky
diodes available from “On Semiconductor” and “Phillips”
respectively. They are suitable for peak repetitive
currents of 300mA or less with good reverse current
characteristics. For applications that are cost driven, the
1N4148 or equivalent will provide sufficient switching
speed with greater forward drop and reduced cost. Other
acceptable diodes are On Semiconductor’s MBR0530 or
Vishay’s B0530, although they can have reverse
currents that exceed 1 mA at very high junction
temperatures. Table 2 summarizes some typical
performance characteristics of various suitable diodes.
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M9999-102507
Micrel, Inc.
MIC2142
t ON(min) =
75°C
VFWD
at
100mA
25°C
VFWD
at
100mA
Room
Temp.
Leakage
at 15V
75°C
Leakage
at 15V
Package
MBR0530
0.275V
0.325V
2.5µA
90µA
SOD123
SMT
1N4148
0.6V
(175°C)
0.95V
25nA
(20V)
0.2µA
(20V)
leaded
and SMT
BAT54
0.4V
(85°C)
0.45V
10nA
(25V)
1µA
(20V)
SMT
BAT85
0.54V
(85°C)
0.56V
0.4µA
2µA
(85°C)
DO-34
leaded
Diode
L max =
VIN(min) 2 × t ON(min) 2
IO(max) × 2 × TS(min)
Series
Type
Package
GRM
ceramic Y5V
surface mount
Vishay
594
tantalum
surface mount
Panasonic
M-series
Electrolytic
leaded
t ON(max) =
Ipeak =
Design Example
Given a design requirement of 12V output and 1mA load
with a minimum input voltage of 2.5V, Equation 2 can be
used to calculate to maximum inductance or it can be
read from the graph in Figure 7. Once the maximum
inductance has been determined the peak current can
be determined using Equation 3 or the graph in Figure
13.
VOUT = 12V
IOUT = 5mA
VIN = 2.5V to 4.7V
Fmax = 360kHz
η = 0.8 = efficiency
Dnom = 0.55
TS(min) =
Fmax
VO
− VIN(min)
η
1.1 × D nom 1.1 × 0.55
=
= 2µsec
Fmin
300kHz
t ON(max) × VIN(max)
L min
2.0 µsec × 4.7V
= 270mA
35 µH
=
Bootstrap Configuration
For input voltages below 4.5V the bootstrap
configuration can increase the output power capability of
the MIC2142. Figure 2 shows the bootstrap configuration
where the output voltage is used to bias the MIC2142.
This improves the power capability of the MIC2142 by
increasing the gate drive volt-age hence the peak
current capability of the internal switch. This allows the
use of a smaller inductor which increases the output
power capability. Table 4 also summarizes the various
configurations and power capabilities using the
booststrap configuration. This bootstrap configuration is
limited to output voltage of 16V or less.
Figure 1 shows how a resistor (R3) can be added to
reduce the ripple seen at the VCC pin when in the
bootstrap configuration. Reducing the ripple at the VCC
pin can improve output ripple in some applications.
Table 3. Capacitor Examples
1
1
2.5 2 × 1.53 µsec 2
1
×
= 42 µH
5mA × 2 × 2.78 µsec 12
− 2.5
0.8
Select 39µH ±10%.
Output Capacitor
Due to the limited availability of tantalum capacitors,
ceramic capacitors and inexpensive electrolyics may be
preferred. Selection of the capacitor value will depend
upon the peak inductor current and inductor size.
MuRata offers the GRM series with up to 10µF @ 25V
with a Y5V temperature coefficient in a 1210 surface
mount package. Low cost applications can use the Mseries leaded electrolytic capacitor from Panasonic. In
general, ceramic, electrolytic, or tantalum values ranging
from 1µF to 22µF can be used for the output capacitor.
MuRata
×
L max =
Table 2. Diode Examples
Manufacturer
D nom
0.55
=
= 1.53 µsec
fmax
360kHz
+3.0V to +4.2V
VIN
L1
33µH
CR1
MBR0530
R3
100
C2
10µF
5
2
EN VCC
1
R2
36.5k
C3
270pF
R1
12.4k
U1 MIC2142
FB SW 3
4
GND
+5V @80mA
C1
22µF
C4
1F
1
=
= 2.78 µsec
360kHz
GND
GND
Figure 1. Bootstrap VCC with VCC Low Pass Filter
October 2007
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M9999-102507
Micrel, Inc.
MIC2142
L1
47µH
VIN
CR1
MBR0530
+5V @16mA
R2
36.5k
R1
12.4k
U1 MIC2142
SW 3
4 FB
C2
10µF
5
GND
2
EN VCC
1
C3
270pF
C1
22µF
GND
GND
Figure 2. Bootstrap Configuration
For additional pre-designed circuits, see Table 4.
L1
10µH
CR1
MBR0530
VIN
+15V @15mA
CR5
LWT673
CR7
LWT673
CR6
LWT673
U1 MIC2142
FB SW 3
4
(from controller)
PWM
GND
2
EN VCC
1
C2
10µF
5
C1
1µF
25V
Rprogram
82
GND
GND
Figure 3. Series White LED Driver with PWM Dimming Control
L1
10µH
CR1
MBR0530
VIN
+15V @15mA
CR5
LWT673
CR7
LWT673
CR6
LWT673
U1 MIC2142
FB SW 3
4
C2
10µF
SHTDWN
5
GND
2
EN VCC
1
C1
1µF
25V
Rprogram
82
GND
DAC
GND
R4
R3
Figure 4. Series White LED Driver with Analog Dimming Control
October 2007
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M9999-102507
Micrel, Inc.
MIC2142
Figure 5. Parallel White LED Driver with Analog Dimming Control
VIN
L1
10µH
CR1
BAT54HT1
+20V @0.5mA
R2
1.8M
C2
10µF
U1 MIC2142
FB SW 3
R1
120k
4
5
GND
2
EN VCC
1
C1
1µF
25V
C1
1µF
25V
VINRTN
GND
Figure 6. Handheld LCD Supply
October 2007
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Micrel, Inc.
MIC2142
VIN(min)
2.5V
VIN(max)
3.0V
VOUT
3.3V
2.5V
4.5V
5V
11.5
boot strapped
boot strapped
12
2.5
4.7
2.5
14.5
4.7
boot strapped
boot strapped
15
2.5
2.5
3.0
4.7
4.7
4.7
3.0
3.0
3.0
3.0
3.0
5.0
8.5
4.7
4.7
14.5
4.7
4.7
4.7
8.5
boot strapped
boot strapped
20
20
5
boot strapped
boot strapped
9
boot strapped
boot strapped
15
boot strapped
boot strapped
20
9
5.0
11.5
12
5.0
14.5
15
5.0
9
9
8.0
11.5
20
12
9
14
15
9
14
20
12
14
15
12
14
20
IOUT(max)
40mA
23mA
10mA
16.5mA
7.8mA
51
77
1.8
2.25
15
22
3.7
1.7
17.4
8
2.7
1.5
40
70
100
15
28
40
7.8
14
21
5.6
70
23
10
43
14
6
30
10
30
8
118
66
30
70
40
18
20
10
6
156
71
27
35
L1
47µH
85µH
180µH
47µH
100µH
15
10
47
100
15
10
47
100
10
22
47
82
33
18
12
33
18
12
33
18
12
33
27
82
180
27
82
180
27
82
27
68
56
100
220
56
100
220
120
220
390
68
150
390
150
IPK @ VIN(max)
129mA
74mA
34VmA
193mA
91mA
605
908
493
232
632
950
622
292
950
430
202
110
287
525
800
520
525
800
886
525
800
287
635
209
95
860
283
129
1083
357
672
237
414
232
105
504
282
128
235
128
72
415
182
72
188
CR1
BAT54
BAT54
BAT54
BAT54
BAT54
MBR0530
MBR
MBR
BAT
MBR
MBR
MBR
BAT
MBR
MBR
BAT
BAT
BAT
MBR
MBR
MBR
MBR
MBR
MBR
MBR
MBR
BAT
MBR
BAT
BAT
MBR
BAT
BAT
MBR
MBR
MBR
BAT
MBR
BAT
BAT
MBR
BAT
BAT
BAT
BAT
BAT
MBR
BAT
BAT
BAT
Table 4. Typical Maximum Power Configuration
October 2007
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M9999-102507
Micrel, Inc.
MIC2142
VIN
3.3V±5%
5V±5%
12V±5%
15V±5%
VOUT
5V
9V
12V
15
20
9V
12V
15V
20
15V
20V
20V
IOUT
70mA
30mA
20mA
15mA
6mA
70mA
40mA
30mA
8mA
158
35
50
L1
18µH
18µH
18µH
18µH
33µH
27µH
27µH
27µH
68µH
68
150
220
CR1
MBR0530
MBR0530
MBR0530
MBR0530
BAT54
MBR0530
MBR0530
MBR0530
BAT54
MBR0530
BAT54
BAT54
IPEAK
400
400
400
400
214
370
370
370
148
350
160
1140
Configuration
Bootstrap
Bootstrap
Bootstrap
Bootstrap
Table 5. Typical Maximum Power Configurations for Regulated Inputs
VIN (V)
2.5
3
3.5
4
5
6
7
8
9
10
11
12
13
14
15
16
VOUT = 16V to 22V
85°C
LMIN (µH)
47
33
47
56
68
82
100
100
120
150
150
150
180
180
220
220
VOUT < 16V (bootstapped)
85°C
LMIN (µH)
47 (15)
33 (18)
27 (22)
27 (22)
27
33
39
47
56
56
68
68
82
82
82
100
VOUT < 16V (bootstapped)
40°C
LMIN (µH)
47 (10)
33 (12)
27 (15)
22 (18)
22
22
27
33
33
39
47
47
56
56
56
68
Table 6. Minimum Inductance
Manufacturer
MuRata
Sumida
Coilcraft
J.W. Miller
Micrel
Vishay
Panasonic
Web Address
www.murata.com
www.sumida.com
www.coilcraft.com
www.jwmiller.com
www.micre.com
www.vishay.com
www.panasonic.com
Table 7. Component Supplier Websites
October 2007
12
M9999-102507
Micrel, Inc.
MIC2142
Inductor Selection Guides
Figure 7. Inductor Selection for VIN = 2.5V
October 2007
Figure 8. Inductor Selection for VIN = 3.0V
13
M9999-102507
Micrel, Inc.
MIC2142
Figure 9. Inductor Selection for VIN = 5V
October 2007
Figure 10. Inductor Selection for VIN = 9V
14
M9999-102507
Micrel, Inc.
MIC2142
IN
Figure 11. Inductor Selection for VIN = 12V
October 2007
Figure 8. Inductor Selection for VIN = 15V
15
M9999-102507
Micrel, Inc.
MIC2142
Figure 13. Peak Inductor Current vs. Input Voltage
October 2007
16
M9999-102507
Micrel, Inc.
MIC2142
Package Information
5-Pin SOT23 (M5)
MICREL, INC. 2180 FORTUNE DRIVE SAN JOSE, CA 95131 USA
TEL +1 (408) 944-0800 FAX +1 (408) 474-1000 WEB http://www.micrel.com
The information furnished by Micrel in this data sheet is believed to be accurate and reliable. However, no responsibility is assumed by Micrel for its
use. Micrel reserves the right to change circuitry and specifications at any time without notification to the customer.
Micrel Products are not designed or authorized for use as components in life support appliances, devices or systems where malfunction of a product
can reasonably be expected to result in personal injury. Life support devices or systems are devices or systems that (a) are intended for surgical implant
into the body or (b) support or sustain life, and whose failure to perform can be reasonably expected to result in a significant injury to the user. A
Purchaser’s use or sale of Micrel Products for use in life support appliances, devices or systems is a Purchaser’s own risk and Purchaser agrees to fully
indemnify Micrel for any damages resulting from such use or sale.
© 2000 Micrel, Incorporated.
October 2007
17
M9999-102507