ACE ACE5018TB15AMA+H Ultra low current consumption 300ma cmos voltage regulator Datasheet

ACE5018T
Ultra Low Current Consumption 300mA CMOS Voltage Regulator
Description
The ACE5018T series are a group of positive voltage regulators manufactured by CMOS
technologies with ultra low power consumption and low dropout voltage, which provide large output
currents even when the difference of the input-output voltage is small. The ACE5018T series can deliver
300mA output current and allow an input voltage as high as 8V. The series are very suitable for the
battery-powered equipment, such as RF applications and other systems requiring a quiet voltage source.
Features

Low Quiescent Current:1.0μA

Operating Voltage Range: 1.8V~8V

Output Current: 300mA

Low Dropout Voltage: 110mV@100mA(VOUT =3.3V)

Output Voltage: 1.2~ 5.0V

High Accuracy: ±2%/±1%(Typ.)

High Power Supply Rejection Ratio: 50dB@1kHz

Low Output Noise:

27xVOUT μVRMS (10Hz~100kHz)

Excellent Line and Load Transient Response

Built-in Current Limiter, Short-Circuit Protection
Application

Portable consumer equipments

Radio control systems

Laptop, Palmtops and PDAs

Wireless Communication Equipments

Portable Audio Video Equipments

Ultra Low Power Microcontroller
VER 1.1
1
ACE5018T
Ultra Low Current Consumption 300mA CMOS Voltage Regulator
Absolute Maximum Ratings(1) Unless otherwise specified, TA=25°C
Parameter
Input Voltage(2)
(2)
Output Voltage
Output Current
Symbol
Max
Unit
VIN
-0.3~9
V
VOUT
-0.3~VIN+0.3
V
IOUT
600
mA
SOT-23-3
Power Dissipation
0.4
SOT-23-5
0.4
Pd
SOT-89-3
W
0.6
DFN1*1-4
0.4
Operating Temperature
Topr
- 40~125
O
C
O
C
Storage Temperature
Tstg
- 40~125
Soldering Temperature & Time
Tsolder
260 OC,10s
Note:
(1)
Stresses beyond those listed under absolute maximum ratings may cause permanent damage to the device.
These are stress ratings only, and functional operation of the device at these or any other conditions beyond
those indicated under recommended operating conditions is not implied. Exposure to absolute-maximum-rated
conditions for extended periods my affect device reliability.
(2)
All voltages are with respect to network ground terminal.
Recommended Operating Conditions
Parameter
MIN.
MAX.
Units
Supply voltage at VIN
1.8
8
V
Operating junction temperature range, Tj
-40
125
°C
Operating free air temperature range, TA
-40
85
°C
VER 1.1
2
ACE5018T
Ultra Low Current Consumption 300mA CMOS Voltage Regulator
Packaging Type
SOT-23-3
SOT-23-3
A
B
C
1
3
3
2
2
3
1
SOT-23-5
SOT-23-5
SOT-89-3
SOT-89-3
DFN1*1-4
DFN1*1-4
Pin Name
Function
2
2
VSS
Ground
1
3
1
VOUT
Output
3
1
4
VIN
Power input
3
CE
Chip Enable Pin
NC
No Connection
Thermal PAD
Ground
A
B
C
2
1
2
1
5
3
2
1
2
3
4
EP
Ordering information
ACE5018T X XX XX + H
Halogen - free
Pb - free
BMA:SOT-23-3A
BMB:SOT-23-3B
BMC:SOT-23-3C
BN:SOT-23-5
AMA:SOT-89-3A
AMB:SOT-89-3B
AMC:SOT-89-3C
IN:DFN1*1-4
Output Voltage:1.2 / 1.5V …../5.0V
A:1%
B:2%
VER 1.1
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ACE5018T
Ultra Low Current Consumption 300mA CMOS Voltage Regulator
Block Diagram
Typical Application Circuit
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ACE5018T
Ultra Low Current Consumption 300mA CMOS Voltage Regulator
Electrical Characteristics
(VIN=VOUT+1V, C IN=COUT =1μF,
TA=25 OC, unless otherwise specified)
Parameter
Symbol
Input Voltage
VIN
Output Voltage Range
VOUT
IOUT =1mA
DC Output Accuracy
Dropout Voltage
Conditions
Vdif(2)
Min
Max
Units
1.8
8
V
1.2
5
V
-2
2
%
-1
1
%
IOUT =100mA,
110
VOUT=3.3V
1.2V≤VOUT
Supply Current
ISS
IOUT =0
≤3.3V
3.3V<VOUT
≤5.0V
Standby Current
Line Regulation
Load Regulation
Temperature Coefficient
ISTBY
CE=VSS
∆VOUT
IOUT =10mA
VOUT ✕∆V IN
VOUT +1V≤VIN≤8V
∆VOUT
VIN= VOUT +1V,
IOUT =10mA,
VOUT ✕∆TA
-40°C<TA<125°C
Output Current Limit
ILIM
Short Current
ISHORT
Power Supply Rejection
Ratio
PSRR
Output Noise Voltage
VON
CE "High" Voltage
VCE“H”
CE "Low" Voltage
VCE“L”
COUT Auto-Discharge
Resistance
RDISCHRG
VOUT=0.5xVOUT(Normal),
VIN = 5V
550
VOUT =VSS
IOUT =50mA
1.5
μA
1.0
1.5
μA
0.1
μA
0.3
%/V
10
mV
100
ppm
700
70
1kHz
50
10kHz
40
100kHz
35
1.5
200
mA
mA
dB
μVRMS
27 x VOUT
BW=10Hz to 100kHz
VCE=VSS
850
20
100Hz
VIN=5V, VOUT =3.0V,
mV
1.0
0.05
1mA≤IOUT≤100mA
∆VOUT
Typ(1)
VIN
V
0.3
V
Ω
NOTE:
(1)
Typical numbers are at 25°C and represent the most likely norm.
(2)
Vdif:The Difference Of Output Voltage And Input Voltage When Input Voltage Is Decreased Gradually Till
Output Voltage Equals To 98% Of VOUT (E).
VER 1.1
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ACE5018T
Ultra Low Current Consumption 300mA CMOS Voltage Regulator
Typical Performance Characteristics
VIN=VOUT +1V, CIN=COUT =1μF,TA=25℃,unless otherwise specified
VER 1.1
6
ACE5018T
Ultra Low Current Consumption 300mA CMOS Voltage Regulator
Application Information
Selection of Input/ Output Capacitors
In general, all the capacitors need to be low leakage. Any leakage the capacitors have will reduce
efficiency, increase the quiescent current.
A recent trend in the design of portable devices has been to use ceramic capacitors to filter DC-DC
converter inputs. Ceramic capacitors are often chosen because of their small size, low equivalent series
resistance (ESR) and high RMS current capability. Also, recently, designers have been looking to ceramic
capacitors due to shortages of tantalum capacitors. Unfortunately, using ceramic capacitors for input
filtering can cause problems. Applying a voltage step to a ceramic capacitor causes a large current surge
that stores energy in the inductances of the power leads. A large voltage spike is created when the stored
energy is transferred from these inductances into the ceramic capacitor. These voltage spikes can easily
be twice the amplitude of the input voltage step.
Many types of capacitors can be used for input bypassing, however, caution must be exercised when
using multilayer ceramic capacitors (MLCC). Because of the self-resonant and high Q characteristics of
some types of ceramic capacitors, high voltage transients can be generated under some start-up
conditions, such as connecting the LDO input to a live power source. Adding a 3Ω resistor in series with
an X5R ceramic capacitor will minimize start-up voltage transients.
The LDO also requires an output capacitor for loop stability. Connect a 1μF tantalum capacitor from OUT
to GND close to the pins. For improved transient response, this output capacitor may be ceramic.
COUT Auto-Discharge Function
ACE5018TB series can discharge the electric charge in the output capacitor (COUT), when a low signal to
the CE pin, which enables a whole IC circuit turn off, is inputted via the
N-channel transistor located between the VOUT pin and the VSS pin (cf. BLOCK DIAGRAM). The COUT
auto-discharge resistance value is set at 200Ω (VOUT=3.0V @ VIN=5.0V at typical). The discharge time of
the output capacitor (COUT) is set by the COUT auto-discharge resistance (R) and the output capacitor
(COUT ). By setting time constant of a COUT auto-discharge resistance value [RDISCHRG] and an output
capacitor value (COUT) as τ (τ=C x RDISCHRG), the output voltage after discharge via the N-channel
transistor is calculated by the following formulas.
( V : Output voltage after discharge, VOUT(E) : Output voltage, t: Discharge time,
τ: COUT auto-discharge resistance RDISCHRG×Output capacitor (COUT) value C)
VER 1.1
7
ACE5018T
Ultra Low Current Consumption 300mA CMOS Voltage Regulator
Packing Information
SOT-23-3
VER 1.1
8
ACE5018T
Ultra Low Current Consumption 300mA CMOS Voltage Regulator
Packing Information
SOT-23-5
VER 1.1
9
ACE5018T
Ultra Low Current Consumption 300mA CMOS Voltage Regulator
Packing Information
SOT-89-3
VER 1.1
10
ACE5018T
Ultra Low Current Consumption 300mA CMOS Voltage Regulator
Packing Information
DFN1*1-4
VER 1.1
11
ACE5018T
Ultra Low Current Consumption 300mA CMOS Voltage Regulator
Notes
ACE does not assume any responsibility for use as critical components in life support devices or systems
without the express written approval of the president and general counsel of ACE Electronics Co., LTD.
As sued herein:
1. Life support devices or systems are devices or systems which, (a) are intended for surgical implant
into the body, or (b) support or sustain life, and shoes failure to perform when properly used in
accordance with instructions for use provided in the labeling, can be reasonably expected to result in
a significant injury to the user.
2. A critical component is any component of a life support device or system whose failure to perform can
be reasonably expected to cause the failure of the life support device or system, or to affect its safety
or effectiveness.
ACE Technology Co., LTD.
http://www.ace-ele.com/
VER 1.1
12
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