[AP1156ADSXX]
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1. Genaral Description
AP1156ADS series is a negative-input negative-output regulator IC using silicon monolithic bipolar structure
which can supply 150mA output current. The output voltage can be set from -1.3 to -1.5V, which is trimmed
in high accuracy. AP1156ADS is supplied with ON/OFF terminal and noise reduction terminal. The ON/OFF
control can be controlled directly with positive logic or CPU. The over current, thermal and reverse bias
protections are integrated.
2. Features
Available to use a small 1.0μF ceramic capacitor
Dropout Voltage VDROP=160mV at 100mA
Output Current 150mA
High Precision output voltage 2.0% or 60mV
Wide operating voltage range -2.8V to -17.0V
Very low quiescent current IQUT=155A at IOUT=0mA
On/Off control (High active)
Built-in Short circuit protection, thermal shutdown
Built-in reverse bias over current protection
Available very low noise application
Very small surface mount package SOT23-5
3. Applications
Battery Powered Systems
DSC, CCD bias, GaAs bias
AP1156ADSXX
Negative Input / Output Voltage LDO Regulator
[AP1156ADSXX]
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4. Table of Contents
1. Genaral Description ....................................................................................................................................1
2. Features .......................................................................................................................................................1
3. Applications ................................................................................................................................................1
4. Table of Contents ........................................................................................................................................2
5. Block Diagram ............................................................................................................................................3
6. Ordering Information ..................................................................................................................................4
7. Pin Configurations and Functions ...............................................................................................................4
8. Absolute Maximum Ratings .......................................................................................................................5
9. Recommended Operating Conditions .........................................................................................................5
10. Electrical Characteristics .........................................................................................................................6
■ Electrical Characteristics (Ta=Tj=25°C) ....................................................................................................6
■ Electrical Characteristics (Ta=-40°C~85°C) ..............................................................................................7
11. Description ..............................................................................................................................................8
11.1 DC Characteristics ...............................................................................................................................8
11.2 Temperature Characteristic ................................................................................................................10
11.3 Load Transient ...................................................................................................................................12
11.4 ON/OFF Transient .............................................................................................................................13
11.5 Line Transient ....................................................................................................................................14
11.6 Ripple Rejection ................................................................................................................................16
11.7 ESR Stability ......................................................................................................................................18
11.8 Operating Region and Power Dissipation ..........................................................................................19
11.9 Application hint .................................................................................................................................20
12. Definition of term ..................................................................................................................................21
13. Test Circuit ............................................................................................................................................22
■Test Circuit .................................................................................................................................................22
14. Package ..................................................................................................................................................23
■ Outline Dimensions ...................................................................................................................................23
15. Revise History .......................................................................................................................................24
IMPORTANT NOTICE ...................................................................................................................................25
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5. Block Diagram
Bandgap
Reference
Over Heat &
Over Current
Protection
VEE
Np
Vout
90k
Cont
GND
Control:High Level On
Figure 1. Block Diagram
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6. Ordering Information
AP1156ADSXX -40 to 85°C SOT23-5
・ Output Voltage Code
For product name, please check the below chart. Please contact your authorized ASAHI KASEI
MICRODEVICES representative for voltage availability.
AP1156ADSXX
Table 1. Standard Voltage Version, Output Voltage & Voltage Code
XX
VOUT
13
-1.3
15
-1.5
Table 2. Optional Voltage Version, Output Voltage & Voltage Code
XX
VOUT
14
-1.4
7. Pin Configurations and Functions
VOUT
GND
NP
(Top View)
5
4
3
2
1
VEE
CONT
Output voltage code
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8. Absolute Maximum Ratings
Parameter
Symbol
min
max
Unit
Condition
Supply Voltage
Vin
-20
0.4
V
|Vin|+|Vcont|20V
Cont Terminal Voltage
Vcont
-0.4
5
V
|Vin|+|Vcont|19V
Reverse Bias Voltage
Vrev
-20
0.3
V
Vin-Vout0.3V
Power Dissipation
PD
-
500
mW
(Note 1)
Junction temperature
Tj
-
150
C
Storage Temperature Range
TSTG
-55
150
C
Note 1. PD must be decreased at the rate of 4.0mW/C for operation above 25C.
WARNING: The maximum ratings are the absolute limitation values with the possibility of the IC breakage.
When the operation exceeds this standard quality cannot be guaranteed.
9. Recommended Operating Conditions
Parameter
Symbol
min
typ
max
Unit
Condition
Operating Temperature Range
Ta
-40
-
85
C
Operating Voltage Range
VOP
-17
-
-2.8
V
|Vin|+|Vcont|19V,
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10. Electrical Characteristics
■ Electrical Characteristics (Ta=Tj=25°C)
The parameters with min or max values will be guaranteed at Ta=Tj=25C.
(Vin=-3.7V, Ta=Tj=25C)
Parameter
Symbol
Condition
min
typ
max
Unit
Vout
Vout
Iout=5mA
(Table 1)
V
Line Regulation
LinReg
ΔVin=5V
-
1
5
mV
Load Regulation
LoaReg
Iout=5mA~50mA
(Table 1)
mV
Iout=5mA~100mA
Iout=5mA~150mA
Quiescent Current
Iq
Iout=0mA
-
155
250
µA
Standby Current
Istandby
Vout Off State
-
0
1
µA
Peak Output Current
IoutMAX
When Vout drops 10%
200
280
-
mA
Short Circuit Current
IShort
-
300
-
mA
Cont Terminal Current
Icont
Vcont=+1.8V
-
12
30
A
Cont Terminal Voltage
Vcont
Vout ON State
1.3
-
-
V
Vout OFF State
-
-
0.3
V
Table 1. Standard Voltage Version
Part Number
Vout
LoaReg
Iout=50mA
Iout=100mA
Iout=150mA
min
typ
max
typ
max
typ
max
typ
max
AP1156ADS13
-1.360
-1.300
-1.240
4
15
8
20
22
50
AP1156ADS15
-1.560
-1.500
-1.440
4
15
8
20
22
50
Table 2. Optional Voltage Version
Part Number
Vout
LoaReg
Iout=50mA
Iout=100mA
Iout=150mA
min
typ
max
typ
max
typ
max
typ
max
AP1156ADS14
-1.460
-1.400
-1.340
4
15
8
20
22
50
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■ Electrical Characteristics (Ta=-40°C~85°C)
The parameters with min or max values will be guaranteed at Ta=-40 ~ 85C.
(Vin=-3.7V, Ta=-40 ~ 85C)
Parameter
Symbol
Condition
min
typ
Max
Unit
Vout
Vout
Iout=5mA
(Table 3, Table 4)
V
Line Regulation
LinReg
ΔVin=5V
-
1
8
mV
Load Regulation
LoaReg
Iout=5mA~50mA
(Table 3, Table 4)
mV
mV
mV
Iout=5mA~100mA
Iout=5mA~150mA
Supply Current
Icc
Iout=0mA
-
155
300
µA
Standby Current
Istandby
Vout Off State
-
0
5
µA
Peak Output Current
IoutMAX
When Vout drops 10%
185
280
-
mA
Short Circuit Current
IShort
-
300
-
mA
Vcont Terminal Current
Icont
Vcont=+1.8V
-
12
30
A
Vcont Terminal Voltage
Vcont
Vout ON State
1.3
-
-
V
Vout OFF State
-
-
0.3
V
Table 3. Standard Voltage Version
Part Number
Vout
LoaReg
Iout=50mA
Iout=100mA
Iout=150mA
min
typ
max
typ
max
typ
max
typ
max
AP1156ADS13
-1.390
-1.300
-1.210
4
16
8
22
22
72
AP1156ADS15
-1.590
-1.500
-1.410
4
16
8
22
22
72
Table 4. Optional Voltage Version
Part Number
Vout
LoaReg
Iout=50mA
Iout=100mA
Iout=150mA
min
typ
max
typ
max
typ
max
typ
max
AP1156ADS14
-1.490
-1.400
-1.310
4
16
8
22
22
72
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11. Description
11.1 DC Characteristics
Unless otherwise specified Vin=-3.5V, Vcont=1.5V, Cin=1.0uF (MLCC),Cout=1.0uF(MLCC),Cnp=0.01uF
Ta=25C
Icont
Vcont
0.01F
1F
VinCin
Vout Cout
Cnp
1
3
2
5
4
VEE
Vout
Np GND
Cont
Iout
VA
1F
A
Iin
Ignd
Iin (Iout=0mA)
Dropout Voltage
0
200
400
600
800
1000
1200
1400
1600
1800
2000
0 5 10 15 20
Vin (-V)
Iin (uA)
0.0
0.1
0.2
0.3
0.4
0.5
0.6
0.7
0.8
0.9
1.0
0 50 100 150
Iout (mA)
Vdrop (V)
0
1
2
3
4
5
6
0 100 200 300 400
Iout (mA)
Ignd (mA)
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Icont VS Vcont (Iout=1mA)
Icc Off Mode (Vcont=1.5V,Iout=0mA)
0
2
4
6
8
10
12
14
16
18
20
0.0 0.5 1.0 1.5 2.0
Vcont (V)
Icont (uA)
1.00E-12
1.00E-11
1.00E-10
1.00E-09
1.00E-08
1.00E-07
1.00E-06
1.00E-05
1.00E-04
0 5 10 15 20
Vin (-V)
Iin (A)
Iin (Iout=0mA) (Enlargement)
IQ (Enlargement)
0
50
100
150
200
250
300
0 5 10 15 20
Vin (-V)
Iin (uA)
0.0
0.1
0.2
0.3
0.4
0.5
0.6
0.7
0.8
0.9
1.0
0 50 100 150
Iout (mA)
IQ (mA)
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11.2 Temperature Characteristic
Unless otherwise specified Vin=-3.5V, Vcont=1.5V, Cin=1.0uF(MLCC),Cout=1.0uF(MLCC),Cnp=0.01uF
Icont
Vcont
0.01F
1F
VinCin
Vout Cout
Cnp
1
3
2
5
4
VEE
Vout
Np GND
Cont
Iout
VA
1F
A
Iin
Vref
1.15
1.16
1.17
1.18
1.19
1.20
1.21
1.22
1.23
1.24
1.25
-40 -20 0 20 40 60 80 100
Ta (℃)
Vref (-V)
IoutMAX (Iout Nonpulse)
IoutMAX (Iout Pulse)
0
50
100
150
200
250
300
-40 -20 0 20 40 60 80 100
Ta (℃)
Iout_MAX (mA)
0
50
100
150
200
250
300
-40 -20 0 20 40 60 80 100
Ta (℃)
Iout_MAX (mA)
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LoadReg
ON/OFF
0
5
10
15
20
25
30
35
40
45
50
-40 -20 0 20 40 60 80 100
Ta (℃)
Load_Reg (mV)
0.0
0.2
0.4
0.6
0.8
1.0
1.2
1.4
-40 -20 0 20 40 60 80 100
Ta (℃)
Vcont (V)
Iin(Iout=0mA)
Icont
100
110
120
130
140
150
160
170
180
190
200
-40 -20 0 20 40 60 80 100
Ta (℃)
Iin (uA)
0
2
4
6
8
10
12
14
16
-40 -20 0 20 40 60 80 100
Ta (℃)
Icont_1.8V (uA)
Icc OFFMode
Vdrop
0
5
10
15
20
25
30
35
40
45
50
-40 -20 0 20 40 60 80 100
Ta (℃)
Icc_Off (nA)
0
100
200
300
400
500
600
700
800
900
-40 -20 0 20 40 60 80 100
Ta (℃)
Vrop (mV)
Io=5-150m
A
Io=5-100m
A
Vout Off
Vout On
Io=50/100/150m
A
Io=5-50mA
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11.3 Load Transient
Unless otherwise specified Vin= Vout(typ)-1.5V, Vcont=1.5V,Cin=1.0uF(MLCC),Cnp=0.01uF
VinCin
Vout Cout
Cnp
1
3
2
5
4
VEE
Vout
Np GND
Cont
Iout
V
Vcont
Iout=5→100mA
Iout=0→100mA
Io=5m
A
Io=100mA
Io=0m
A
Io=100m
A
Cout=1.0uF(MLCC) 500mV/div
Cout=2.2uF(MLCC) 500mV/div
Cout=1.0uF(Tantalum) 200mV/div
Cout=2.2uF(Tantalum) 200mV/div
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11.4 ON/OFF Transient
Vin= -3.5V, Cin=1.0uF (MLCC),Cnp=0.01uF,Iout=100mA, Control f=1Hz(Cnp Full discharge)
ON Transient Cnp Variable
VinCin Vout Cout
Cnp
Vcont=0→1.5→0
1
3
2
5
4
VEE
Vout
Np GND
Cont
Iout
V
ON Transient Cout Variable
OFF Transient Cnp Variable
Vout 2V/div
Vcont 1V/div
Vout 2V/div
←0V
0V
←0V
Vcont 2V/div
Vout 2V/div
Vcont 1V/div
Cout=1.0/2.2/4.7/10uF
O
N
O
F
F
O
N
O
F
F
O
F
F
O
N
Cnp=1000pF,0.01uF,0.1u
F
Cnp=1000pF,0.01uF,0.1u
F
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11.5 Line Transient
Vin=-Vout(typ)-1.5→-Vout(typ)-2.5V, Vcont=1.5V,Cin=1.0uF(MLCC),Cnp=0.01uF,Iout=100mA
Cin=1.0uF(MLCC) Iout=5mA
Cin=1.0uF(MLCC) Iout=100mA
Cin=1.0uF(MLCC) Iout=5mA
Cin=1.0uF(MLCC) Iout=100mA
Cout=1.0uF(MLCC) 100mV/div
Cout=1.0uF(Tantalum) 100mV/div
Cout=1.0uF(MLCC) 100mV/div
Cout=1.0uF(Tantalum) 100mV/div
Cout=2.2uF(MLCC) 100mV/div
Cout=2.2uF(Tantalum) 100mV/div
Vin=-6.5V
Vin=-7.5V
Vin=-7.5V
Vin=-6.5V
Vin=-6.5V
Vin=-7.5V
Vin=-6.5V
Vin=-7.5V
Cout=2.2uF(MLCC) 100mV/div
Cout=2.2uF(Tantalum) 100mV/div
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Cin=1.0uF(Tantalum) Iout=5mA
Cin=1.0uF(Tantalum) Iout=100mA
Cin=1.0uF(Tantalum) Iout=5mA
Cin=1.0uF(Tantalum) Iout=100mA
Cout=1.0uF(MLCC) 100mV/div
Cout=1.0uF(Tantalum) 100mV/div
Vin=-6.5V
Vin=-7.5V
Cout=1.0uF(MLCC)100mV/div
Cout=1.0uF(Tantalum) 100mV/div
Vin=-6.5V
Vin=-7.5V
Cout=2.2uF(MLCC) 100mV/div
Cout=2.2uF(Tantalum) 100mV/div
Cout=2.2uF(Tantalum) 100mV/div
Cout=2.2uF(MLCC) 100mV/div
Vin=-6.5V
Vin=-7.5V
Vin=-6.5V
Vin=-7.5V
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11.6 Ripple Rejection
Vin=-3.5(V) Vcont=1.5V, Vripple=500mVp-p,Cnp=0.01uF,Iout=10mA
View point
Cout
Cnp
1
3
2
5
4
VEE
Vout
Np GND
Cont
Iout
Vripple=500mVp-p
Vin=Vouttyp-2.0V
Cout=1.0uF(Tantalum),Iout=5mA
Cout=1.0uF(MLCC),Iout=5mA
Cout=1.0uF(Tantalum),Iout=100mA
Cout=1.0uF(MLCC),Iout=100mA
10dB/div
0dB→
10dB/div
0dB→
10dB/div
0dB→
10dB/div
0dB→
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Cout=2.2uF(Tantalum),Iout=5mA
Cout=2.2uF(MLCC),Iout=5mA
Cout=2.2.uF(Tantalum),Iout=100mA
Cout=2.2uF(MLCC),Iout=100mA
10dB/div
0dB→
10dB/div
0dB→
10dB/div
0dB→
10dB/div
0dB→
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11.7 ESR Stability
IC does operate with 1.0uF Cout. If it is 1.0uF or larger, the capacitor of any type can be used in all range
without considering ESR. But due to the parts are uneven, please enlarge the capacitance as much as possible.
With larger capacity, the output noise decreases more. In addition, the response to the load change, etc. can be
improved. The IC won’t be damaged by enlarging the capacity.
The input capacitor is necessary in case the battery voltage drops, the power supply impedance increases, or
the distance to the power supply is far. 1 input capacitor might be necessary for each 1 IC or for several ICs. It
depends on circuit condition. Please confirm the stability by each circuit.
Generally, Multi-layer ceramic capacitor (MLCC) has the temperature characteristic and the voltage
characteristic. Please select parts in consideration of the voltage and the temperature used.
0.01
0.1
1
10
100
0 50 100 150
Iout (mA)
ESR (Ω)
Figure 2. Stability area graph
Condition:Vin=Vout(typ)-1.5V Cin=0.1μF, Cout=1.0μF (MLCC)
The output can be seen as oscillated when the overheating protection or the overcurrent protection start
operation, or the input voltage is low. In this case, please lower the power consumption, decrease the load
current or make the input voltage higher.
Generally, a ceramic capacitor has the temperature characteristic and the voltage characteristic. Please select
parts in consideration of the voltage and the temperature used. ASAHI KASEI TOKO POWER DEVICES
recommend B characteristic type.
Figure 3. (Left) Capacitance vs. Voltage; (Right) Capacitance vs. Temperature
Stable area
Unstable area
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11.8 Operating Region and Power Dissipation
The power dissipation of the device is dependent on the junction temperature. Therefore, the package
dissipation is assumed to be an internal limitation. The package itself does not have enough heat radiation
characteristic due to the small size. Heat runs away by mounting IC on PCB. This value changes by the
material, copper pattern etc. of PCB.
The overheating protection operates when there is a lot of loss inside the regulator (Ambient temperature high,
heat radiation bad, etc.). The output current and the output voltage will drop when the protection circuit
operates. When joint temperature (Tj) reaches the set temperature, IC stops the operation. However, operation
begins at once when joint temperature (Tj) decreases.
・The thermal resistance when mounted on PCB
The chip joint temperature during operation is shown by Tj=θja×Pd+Ta. Joint part temperature (Tj) of
AP1156ADSxx is limited around 150°C with the overheating protection circuit. Pd is the value when the
overheating protection circuit starts operation. When you assume the ambient temperature to be 25°C,
150=θja×Pd(W)+25
θja×Pd=125
θja=125/Pd (°C/W)
・Example of mounting substrate
Figure 4. PCB Material: Two layer glass epoxy substrate
(x=30mm,y=30mm,t=1.0mm,Copper pattern thickness 35um)
Please do derating with 5.9mW/°C at Pd=736mW and 25°C or higher. Thermal resistance is (θja=170°C/W)
・Method of obtaining Pd easily
Connect output terminal to GND(short circuited), and measure the input current by increasing the input
voltage gradually up to 10V. The input current will reach the maximum output current, but will decrease soon
according to the chip temperature rising, and will finally enter the state of thermal equilibrium (natural air
cooling) The input current and the input voltage of this state will be used to calculate the Pd.
Pd(mW) Vin (V) Iin (mA)
When the device is mounted, mostly achieve 600mW or more.
025 50 75 100 150
Pd(mW)
Pd
D Pd
2
3
5
4
Ta (℃)
Procedure (When mounted on PCB).
1.Find Pd (Vin×Iin when the output is short-circuited).
2. Plot Pd against 25°C.
3. Connect Pd to the point corresponding to the 150°C with a
straight line.
4. Pull a vertical line from the maximum operating
temperature in your design (e.g., 75°C).
5. Read the value of Pd against the point at which the
vertical line intersects the derating curve(DPd).
6.DPd÷(Vinmax-Vout)=Iout (at 75°C)
Figure 5. Method of obtaining Pd
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The maximum output current at the highest operating temperature will be Iout≒DPd÷(Vinmax-Vout).
Please use the device at low temperature with better radiation. The lower temperature provides better quality.
・The operation area
Pd when mounted on the substrate as shown on the Figure 4. (Ta=25°C)
SOT23-5=736mW (derating –5.9mW)
The current which can be used continuously with Ta=25°C min is calculated by the following.
VoutVin Ta
mAIout
)25(9.5736
)(
… SOT23-5
*Iout<150mA
The operation area is the part enclosed in the line including the “0” mentioned in graph1
The overheating sensor may operate, or the output voltage may drop outside those area.
The heat radiation characteristic changes in various conditions, so please check under your condition.
IoutMAX vs IN-OUT VOLTAGE DIFF
(SOT23L-6)
0
20
40
60
80
100
120
140
160
0 1 2 3 4 5 6 7 8 9 10
IN-OUT VOLTAGE DIFF (V)
Iout MAX (mA)
Ta=+85℃
Ta=+70℃
Ta=+50℃
Ta=+25℃
Figure 6. SOT23-5
11.9 Application hint
Positive REG
TK721xxC
Negative REG
Vout
Vout
Load
Figure 7.
When using positive output regulator together with this device, sometimes the voltage may not be outputted.
To solve this problem, please connect Schottkey diode between GND and output, or change the timing of
On/Off.
025 50 85 125 150
Ta (℃)
Pd (mW)
200
400
600
800
1000
単体 -4.2mW/℃
基板実装時 -7.1mW/℃
Installed On a PCB
-5.9mW/°C
SOT23-5
Unit
-4.2mW/°C
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12. Definition of term
■Relating Characteristic
Each characteristic will be measured in a short period not to be influenced by joint temperature (Tj).
・Output voltage (Vout)
The output voltage is specified with Vin= Vout(typ)+1V and Iout=5mA
・Output current (Iout)
Output current, which can be used continuously (It is the range where overheating protection of the IC does not
operate.)
・Peak output current (IoutPEAK)
The rated output current is specified under the condition where the output voltage drops 90% by increasing the
output current, compared to the value specified at Vin=Vout(typ)-1.5V.
・Dropout voltage (Vdrop)
It is an I/O voltage difference when the circuit stops the stable operation by decreasing the input voltage.
It is measured when the output voltage drops 100mV from its nominal value by decreasing the input voltage
gradually.
・Line Regulation (LinReg)
It is the fluctuations of the output voltage value when the input voltage is changed.
・Load Regulation (LoaReg)
It is the fluctuations of output voltage value when the input voltage is assumed to be Vout(typ) -1.5V, and the
load current is changed.
・Ripple Rejection (R.R)
Ripple rejection is the ability of the regulator to attenuate the ripple content of the input voltage at the output.
It is measured with the condition of Vin=Vout-2.0V. Ripple rejection is the ratio of the ripple content
between the output vs. input and is expressed in dB
・Standby current (Istandby)
It is an input current which flows to the Cont terminal, when the IC is turned off.
■Relating Protection Circuit
・Over Current Protection
It is a function to protect the IC by limiting the output current when excessive current flows to IC, such as the
output is connected to GND, etc.
・Thermal Protection
It protects the IC not to exceed the permissible power consumption of the package in case of large power loss
inside the regulator.
The output is turned off when the chip reaches around 150℃, but it turns on again when the temperature of the
chip decreases.
[AP1156ADSXX]
014011333-E-00 - 22 - 2014/10
13. Test Circuit
■Test Circuit
DC
Load Transient
Icont
Vcont
0.01F
1F
VinCin
Vout Cout
Cnp
1
3
2
5
4
VEE
Vout
Np GND
Cont
Iout
VA
1F
A
Iin
VinCin
Vout Cout
Cnp
1
3
2
5
4
VEE
Vout
Np GND
Cont
Iout
V
Vcont
Line Transient
ON/OFF Transient
Cin
Vout Cout
Cnp
1
3
2
5
4
VEE
Vout
Np GND
Cont
Iout
V
↑
Vin=Vouttyp-2.5V
Vin=Vouttyp-1.5V
↓
Vin
Vcont
VinCin Vout Cout
Cnp
Vcont=0→1.5→0
1
3
2
5
4
VEE
Vout
Np GND
Cont
Iout
V
Ripple Rejection
ESR Stability
View point
Cout
Cnp
1
3
2
5
4
VEE
Vout
Np GND
Cont
Iout
Vripple=500mVp-p
Vin=Vouttyp-2.0V
VinCin
Vout
Cout
Cnp
1
3
2
5
4
VEE
Vout
Np GND
Cont
Iout
VESR
Vcont
External Components
MLCC: Multi layer Ceramic Capacitor
Tantalum: Tantalum Capacitor
Figure 8. Test Circuit
[AP1156ADSXX]
014011333-E-00 - 23 - 2014/10
14. Package
■ Outline Dimensions
(Unit:mm)
2.9
1.6
1.1
0.125
0.4
2.8
0 ~0.15 0.1
0.2
5 4
1 3
+0.10
0.05
0.4 0.2
+
+
+
0.95 0.95
R33
Mark
Lot No.
xxx
0.1
+
+0.2
0.1
+0.2
0.3
[AP1156ADSXX]
014011333-E-00 - 24 - 2014/10
15. Revise History
Date
(YY/MM/DD)
Revision
Page
Contents
14/10/29
00
-
First Edition
[AP1156ADSXX]
014011333-E-00 - 25 - 2014/10
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