ADMOS AMS116L-X

Advanced
Monolithic
Systems
AMS116
100mA LOW DROPOUT VOLTAGE REGULATOR
RoHS compliant
FEATURES
APPLICATIONS
• 5V Version Available*
• Output Current of 100mA
• Very Low Quiescent Current
• Reverse Battery Protection
• Input-output Differential less than 0.6V
• Short Circuit protection
• Internal Thermal Overload Protection
• Battery Powered Systems
• Portable Consumer Equipment
• Cordless Telephones
• Portable (Notebook) Computers
• Portable Instrumentation
• Radio Control Systems
• Personal Communication Equipment
• Toys
• Low Voltage Systems
GENERAL DESCRIPTION
The AMS116 series consists of positive fixed voltage regulators ideally suited for use in battery-powered systems. These
devices feature very low quiescent current of 1mA or less when supplying 10mA loads. This unique characteristic and the
extremely low input -output differential required for proper regulation (0.2V for output currents of 10mA) make the AMS116
ideal to use for standby power systems.
Like other regulators the AMS116 series also includes internal current limiting, thermal shutdown, and is able to withstand
temporary power-up with mirror-image insertion.
The AMS116 is offered in the 3-pin TO-92 package and SOT-89 package.
ORDERING INFORMATION
PACKAGE TYPE
PIN CONNECTIONS
OPER. TEMP
TO-92
SOT-89
RANGE
AMS116N-X
AMS116L-X
IND
X =5V
*For additional available fixed voltages contact factory
TO-92
Plastic Package (N)
OUTPUT
SOT-89 Package
(L)
INPUT
1
GND
INPUT
Bottom View
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2
GND
3
OUTPUT
Top View
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AMS116
ABSOLUTE MAXIMUM RATINGS (Note 1)
Input Voltage
Operating Voltage Range
Load Current
Internal Power Dissipation
18V
2.5V to 16V
150mA
Internally Limited
Maximum Junction Temperature
+125°C
Storage Temperature
-65°C to +150°C
Lead Temperature (Soldering 25 sec)
265°C
ESD
2000V
ELECTRICAL CHARACTERISTICS
Electrical Characteristics at TJ=25°C, C2 = 100µF unless otherwise specified.
PARAMETER
CONDITIONS
Min.
(Note 2)
Output Voltage
V = VOUT+3V
Line Regulation
V = VOUT+3V to 14V
Load Regulation
AMS116-X
Typ.
+3
%
2
30
mV
5mA ≤I ≤ 100 mA
15
60
mV
Dropout Voltage
IO ≤ 30 mA
IO = 100 mA
80
170
150
330
mV
mV
Quiescent Current
IO ≤ 10 mA, V = VOUT+3V to 14V
IN
400
1000
µA
Ripple Rejection
fO = 120Hz
Temperature Coefficient
-3
Units
Max.
IN
IN
O
IO ≤ 10 mA, V = VOUT+3V to 14V
IN
80
dB
±.35
mV/°C
Note 1: Absolute Maximum Ratings are limits beyond which damage to the device may occur. For guaranteed performance limits and associated test
conditions, see the Electrical Characteristics tables.
Note 2: See Circuit in Typical Applications. To ensure constant junction temperature, low duty cycle pulse testing is used.
Note 3: Limits appearing in boldface type apply over the entire junction temperature range for operation. Limits appearing in normal type apply for TA = TJ =
25°C.
+
VIN
+
VOUT
Figure 1. SOT-89 Board Layout
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AMS116
APPLICATION HINTS
Package Power Dissipation
5.
The package power dissipation is the level at which the thermal
sensor monitoring the junction temperature is activated. The
AMS116 shuts down when the junction temperature exceeds the
limit of 150°C. The junction temperature rises as the difference
between the input power and output power increases. The
mounting pad configuration on the PCB, the board material, as
well as the ambient temperature affect the rate of temperature rise.
The junction temperature will be low, even if the power
dissipation is high, when the mounting of the device has good
thermal conductivity. When mounted on the recommended
mounting pad (figure1) the power dissipation for the SOT-89
package is 600mW. For operation above 25°C derate the power
dissipation at 4.8mW/°C. To determine the power dissipation for
shutdown when mounted, attach the device on the PCB and
increase the input-to-output voltage until the thermal protection
circuit is activated. Calculate the power dissipation of the device
by subtracting the output voltage from the input voltage and
multiply by the output current. The measurements should allow
for the ambient temperature of the PCB. The value obtained from
PD/ (150°C - TA) is the derating factor. The PCB mounting pad
should provide maximum thermal conductivity in order to
maintain low device temperatures. As a general rule, the lower the
temperature, the better the reliability of the device.
The thermal resistance when the device is mounted is equal to:
TJ = θJA x PD + TA
The internal limit for junction temperature is 150°C. If the ambient
temperature is 25°C, then:
150°C = θJA x PD + 25°C
θJA = 125°C/ PD
A simple way to determine PD is to calculate VIN x IIN when the
output is shorted. As the temperature rises, the input gradually will
decrease. The PD value obtained when the thermal equilibrium is
reached, is the value that should be used.
The range of usable currents can be found from the graph in figure
2.
(mW)
3
PD
6
DPD
4
5
25
50
75
T (°C)
150
Figure 2
Procedure:
1. Find PD.
2. PD1 is calculated as PD x (0.8 - 0.9).
3. Plot PD1 against 25°C.
4. Connect PD1 to the point corresponding to the 150°C.
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Take a vertical line from the maximum operating temperature
(75°C) to the derating curve.
6. Read the value of PD at the point where the vertical line
intersects the derating curve. This is the maximum power
dissipation, DPD.
The maximum operating current is:
IOUT = (DPD/ (VIN(MAX) - VO)
External Capacitors
The AMS116 series require an output capacitor for device
stability. The value required depends on the application circuit
and other factors.
Because high frequency characteristics of electrolytic capacitors
depend greatly on the type and even the manufacturer, the value
of capacitance that works well with AMS116 for one brand or
type may not necessary be sufficient with an electrolytic of
different origin. Sometimes actual bench testing will be the only
means to determine the proper capacitor type and value. To obtain
stability in all general applications a high quality 100µF
aluminum electrolytic or a 47µF tantalum electrolytic can be used.
A critical characteristic of the electrolytic capacitors is their
performance over temperature. The AMS116 is designed to
operate to -40°C, but some electrolytics will freeze around -30°C
therefore becoming ineffective. In such case the result is
oscillation at the regulator output. For all application circuits
where cold operation is necessary, the output capacitor must be
rated to operate at the minimum temperature. In applications
where the regulator junction temperature will never be lower than
25°C the output capacitor value can be reduced by a factor of two
over the value required for the entire temperature range (47µF for
a high quality aluminum or 22µF for a tantalum electrolytic
capacitor).
With higher output currents, the stability of AMS116 decreases.
Considering the fact that in many applications the AMS116 is
operated at only a few milliamps (or less) of output current, the
output capacitor value can be reduced even further. For example,
a circuit that is required to deliver a maximum of 10mA of output
current from the regulator output will need an output capacitor of
only half the value compared to the same regulator required to
deliver the full output current of 100mA.
As a general rule, with higher output voltages the value of the
output capacitance decreases, since the internal loop gain is
reduced.
In order to determine the minimum value of the output capacitor,
for an application circuit, the entire circuit including the capacitor
should be bench tested at minimum operating temperatures and
maximum operating currents. To maintain internal power
dissipation and die heating to a minimum, the input voltage should
be maintain at 0.6V above the output. Worst-case occurs just after
input power is applied and before the die had the chance to heat
up. After the minimum capacitance value has been found for the
specific brand and type of electrolytic capacitor, the value should
be doubled for actual use to cover for production variations both
in the regulator and the capacitor.
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AMS116
TYPICAL PERFORMANCE CHARACTERISTICS
INPUT OUTPUT DIFFERENTIAL (V)
IO = 100mA
0.4
0.3
IO = 50mA
0.2
IO = 10mA
0.1
0
0.6
0.4
0.2
0
Load Transient Response
50
OUTPUT CURRENT (mA)
100
40
-40
~
~
~
~
150
250
TJ= 25°C
200
150
TJ = -40°C
100
50
15
30
TIME (µs)
45
~
~
~
~
IO = 50mA
2
0
-40
IO = 0mA
0
40
80
120
TEMPERATURE (° C)
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QUIESCENT CURRENT ( mA)
15
1
0
0
15
30
TIME (µs)
45
VIN = 14V
25
20
15
10
5
30
Ripple Rejection
35
85
30
80
25
20
IO= 100mA
15
10
5
60
30
90
OUTPUT CURRENT (mA)
0
Quiescent Current
20
3
3
0
20
10
INPUT VOLTAGE (V)
0
Quiescent Current
10
TJ = 85°C
0
0
~
~
Quiescent Current
QUIESCENT CURRENT (mA)
0
VIN = VOUT = 9V
C2= 100 µF
30
C2= 100µF
0
3
2
1
0
-1
-2
~
-3 ~
Peak Output Current
300
RIPPLE REJECTION (dB)
OUTPUT VOLTAGE
DEVIATION (mV)
0.8
0
25
QUIESCENT CURRENT (mA)
Line Transient Response
1.0
80
40
120
JUNCTION TEMPERATURE (° C)
OUTPUT CURRENT ( mA)
INPUT OUTPUT DIFFERENTIAL (V)
0.5
0
LOAD CURRENT(mA)
Dropout Voltage
1.2
INPUT VOLTAGE OUTPUT VOLTAGE
CHANGE (V)
DEVIATION (mV)
Dropout Voltage
0.6
IO= 50mA
0
C2 = 100µF
TANTALUM
75
C2 = 100µF
ALUM
70
65
60
55
IO= 10mA
50
IO= 10mA
-5
-20 -10
0 10 20 30 40 50 60
INPUT VOLTAGE (V)
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1
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10
100 1k 10k 100k
FREQUENCY (Hz)
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1M
AMS116
TYPICAL PERFORMANCE CHARACTERISTICS (Continued)
80
80
75
70
65
60
55
FQ= 120Hz
50
45
0
25
50
75
OUTPUT CURRENT (mA)
75
70
65
60
55
FQ= 120Hz
50
45
100
Output Capacitor ESR
0
25
50
75
OUTPUT CURRENT (mA)
Maximum Power Dissipation (TO-92)
0.7
0.125" Lead Lenght
from PC Board
0.6
0.4" Lead
Lenght from
PC Board
0.3
0.2
0.1
0
POWER DISSIPATION (W)
POWER DISSIPATION (W)
1.0
0.9
0.8
100
COUT= 100µF
VO = 5V
10
1
STABLE
REGION
0.1
0.01
0
80
20
40
60
OUTPUT CURRENT (mA)
Maximum Power Dissipation (SOT-89)
1.0
0.9
0.5
0.4
100
EQUIVALENT SERIES RESISTANCE ( Ω)
Ripple Rejection
85
RIPPLE REJECTION (dB)
RIPPLE REJECTION (dB)
Ripple Rejection
85
MOUNTED
ON PCB
0.8
0.7
0.6
0.5
0.4
0.3
UNMOUNTED
0.2
0.1
0
0 10 20 30 40 50 60 70 80
AMBIENT TEMPERATURE (° C)
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0 10 20 30 40 50 60 70 80 90
AMBIENT TEMPERATURE (° C)
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100
AMS116
TYPICAL APPLICATIONS
Voltage Regulator Circuit
VIN
UNREGULATED
INPUT
Voltage Boost Circuit
C1*
0.1µF
GND
AMS116
VOUT
REGULATED
OUTPUT
AMS116
+
IQ
VO
1µF
C2**
100µF
IQ
*Required if regulator is located far from power supply filter.
**C2 must be at least 100µF to maintain stability; it can be increased
without bound to maintain regulation during transients and it should be
located as close as possible to the regulator. This capacitor must be rated
over the same operating temperature range like the regulator. The ESR
of this capacitor is critical (see curve).
+
47µF
VOUT
R
VOUT = VO+IQR
Current Boost Circuit
Current Regulator Circuit
IO
100
AMS116
R
AMS116
+
10µF
+
GND
+
VIN
1µF
+
VO
47µF
47µF
IQ
IO = (VO/R )+ IQ
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AMS116
PACKAGE DIMENSIONS inches (millimeters) unless otherwise noted.
3 LEAD TO-92 PLASTIC PACKAGE (N)
0.180±0.005
(4.572±0.127)
0.060±0.005
(1.524±0.127)
DIA
0.060±0.010
(1.524±0.254)
0.90
(2.286)
NOM
0.180±0.005
(4.572±0.127)
0.140±0.010
(3.556±0.127)
5° NOM
0.500
(12.70)
MIN
0.050
(1.270)
MAX
UNCONTROLLED
LEAD DIMENSIONS
0.015±0.002
(0.381±0.051)
0.016±0.003
(0.406±0.076)
0.050±0.005
(1.270±0.127)
10°
NOM
N (TO-92 ) AMS DRW# 042391
SOT-89 PLASTIC PACKAGE (L)
0.173-0.181
(4.40-4.60)
0.055-0.063
(1.40-1.60)
0.014-0.017
(0.35-0.44)
0.064-0.072
(1.62-1.83)
0.155-0.167
(3.94-4.25)
0.084-0.090
(2.13-2.29)
0.090-0.102
(2.29-2.60)
0.035-0.047
(0.89-1.20)
0.059
(1.50)
BSC
0.014-0.019
(0.36-0.48)
0.017-0.022
(0.44-0.56)
L (SOT-89 ) AMS DRW# 042392
0.118
(3.00)
BSC
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