ETC RE031

Features
•
•
•
•
•
•
•
Low Quiescent Current, Low Drop Out Voltage Regulator
2.5V Fixed Output Voltage
3V to 5.5V Supply Operation
5 mA Maximum Load Current
Power-down Mode Consumption Less Than 1 µA
0.35 µm CMOS Technology
Typical Application: Real Time Clock (RTC), Backup Battery Supply in Mobile
Terminals
• Maximum Current Consumption 10 µA
Description
RE031 is a Low Drop Out (LDO) voltage regulator macrocell with a fixed 2.5V output
voltage, rated for loads up to 5 mA. It is designed to be integrated with other analog
cells, digital logic, microcontrollers, DSP cores and memory blocks into system-onchip products.
The circuit consists of a PMOS pass device, an error amplifier and a feedback resistive network, sized to achieve the required closed loop gain. These blocks make up
the regulating loop. An internal reference voltage (bandgap voltage) has been
included. The target reference voltage is 1.2V, with a tolerance of 4%, delivered by an
external trimming code. Current reference is generated inside the cell through a circuit
supplied by VBAT. The remote sense terminal, VSAUVS, provides regulation at the load,
by connecting it together with the output terminal, V SAUV,, near a critical point to
improve the regulation performance (e.g., connecting them at the package pin by double bonding thus avoiding the bonding resistance influence). A capacitor of 2.2 µF
connected from VSAUV to ground is needed as external compensation.
Figure 1. Symbol(1)
trimbg20[9:0]
vbat2a
BG020
Embedded ASIC
Macrocell:
Power
Management for
Mobile
Terminals (PM)
RE031
Fixed 2.5V
5 mA
Low Quiescent
Current
LDO Voltage
Regulator
rst
vsauv
vbg20
vsauvs
vsauvc
Note:
gnd2
1. Pin names are written as they appear on the user screen when the symbol is
opened in the design tool environment.
Rev. 2707B–PMGMT–03/03
1
Functional Diagram
Figure 2. Functional Diagram
VBAT2A
TRIMBG20[9:0]
BANDGAP
and
IBIAS
Iref
Pass
Device
Vref
VSAUVC
VSAUV
RST
GND2
GND2
VSAUVS
VBG20
R1
R2
GND2
Pin Description
Pin Name
I/O
Type
Function
Value
VBAT2A
Power supply
External pad
Power supply
3V to 5.5V
VSAUV
Analog output
External pad
Output voltage
2.4V to 2.6V
VSAUVS
Analog input
External pad
Sense voltage
2.4V to 2.6V
VSAUVC
Analog output
Internal pin
Output voltage
2.4V to 2.6V
GND2
Ground
Internal pin
Ground
0
Digital bus
Internal pin
Bandgap Reference Trimming
0 to VSAUV
RST
Digital output
Internal pin
POR signal
0 to VSAUV
VBG20
Analog output
Internal pin
Voltage reference
1.231V
TRIMBG20
2
RE031 2.5V 5 mA LDO Voltage Regulator
2707B–PMGMT–03/03
RE031 2.5V 5 mA LDO Voltage Regulator
Absolute Maximum Ratings*
VIN .......................................................... -0.3V to 6.5V
*NOTICE:
Digital Signals......................................... -0.3V to 5.5V
Output Current..................................Internally Limited
Junction Temperature ..........................-20°C to 150°C
Stresses beyond those listed under “Absolute Maximum Ratings” may cause permanent damage to the
device. This is a stress rating only and functional
operation of the device at these or other conditions
beyond those indicated in the operational sections of
this specification is not implied. Exposure to absolute
maximum rating conditions for extended periods may
affect device reliability.
Electrical Specifications(1)
TA = -20°C to +85°C, supply voltage = 3V to 5.5V unless otherwise specified, output capacitance = 2.2 µF.
Table 1. Electrical Characteristics
Symbol
Parameter
VSAUVC
Condition
Min
Typ
Max
Unit
Auxiliary Operating Supply Voltage
2.4
2.5
2.6
V
VSAUV
Output Voltage
2.4
2.5
2.6
V
ISAUV
Output Current
5
mA
IQQ
Quiescent Current
10
µA
∆VDC
Line Regulation
ISAUV = 5 mA
12
mV
∆VTRAN
Transient Line Regulation
ISAUV = 5 mA
rise time = fall time = 5 µs
37
mV
∆VDC
Load Regulation
10% - 90% of max ISAUV
10
mV
∆VTRAN
Transient Load Regulation
10% - 90% of max ISAUV
rise time = fall time = 5 µs
5
mV
@100 Hz
-55
dB
@1 kHz
-35
dB
@20 kHz
-12
dB
@100 kHz
-12
dB
@100 Hz
-50
dB
@1 kHz
-35
dB
@20 kHz
-13
dB
@100 kHz
-13
dB
@100 Hz
-40
dB
@1 kHz
-35
dB
@20 kHz
-13
dB
@100 kHz
-10
dB
1051
µ VRMS
VBAT = 3V
Power Supply Rejection Ratio
at Full Load
PSRR
VBAT = 4.25V
VBAT = 5.5V
VN
Output Noise
ISD
Shut Down Current
Note:
Bandwidth = 10 Hz to 100 kHz;
output current = 5 mA
1
µA
1. Obtained by considering the parasitics of a TFBGA100 Package.
3
2707B–PMGMT–03/03
Control Modes
Trimming
The bandgap inside RE031 has trimming capability, i.e., it is possible to compensate the
bandgap resistance variations due to process gradients through the TRIMBG20[9:0] signal. In order to reduce the sensitivity of the bandgap voltage to resistance varitions, the
trimming has been designed to compensate up to ±40% of resistance variations.
Table 2. Truth Table
Application Example
Resistance Variation
TRIMBG20[9:0]
+35% to +40%
1001000000
+20% to +35%
0101000000
+5% to +25%
0011000000
-5% to +5%
0000000000
-15% to -5%
0001100000
-22.5% to -15%
0001010000
-27.5% to -22.5%
0001001000
-32.5% to -27.5%
0001000100
-35% to -32.5%
0001000010
-37.5% to -35%
0001000001
-40% to -37.5%
0001000000
A ceramic capacitor of 2.2 µF with ESR between 20 mΩ and 250 mΩ connected from
VSAUV to ground is needed for external compensation.
Description
Min
Typ
Max
Units
Capacitor (CL)
1.8
2.2
2.6
µF
Figure 3. Application Example
Internal
Voltage Reference
VBAT2A
Battery
Pack
TRIMBG20[9:0]
Digital
Core
RST
VSAUV
VBG20
VSAUVC
VSAUVS
CL
GND2
4
RE031 2.5V 5 mA LDO Voltage Regulator
2707B–PMGMT–03/03
RE031 2.5V 5 mA LDO Voltage Regulator
Typical Performance Characteristics (Conditions specified on page 7.)
S ta tic L o a d R e g u la tio n
Static Line Regulation at Full Load
V BA T= 3V
V BA T= 5,5V
Battery Voltage [V]
T ra n s ie n t L o a d R e g u la tio n
O u tp u t V o lta g e C h a n g e [m V ]
Output Voltage Change [mV]
IL [m A ]
Transient Line Regulation at Full Load
V BA T= 4,25V
V BA T= 5,5V
V BA T= 3V
V BA T= 4,25V
O u tp u tV o lta g e C h a n g e [m V ]
Output Voltage Change [mV]
Time [ms]
T im e [m s]
5
2707B–PMGMT–03/03
Typical Performance Characteristics (Conditions specified on page 7.)
P o w e r S u p p ly R e je c tio n R a tio a t F u ll L o a d
P o w e r S u p p ly R e je c tio n R a tio a t F u ll L o a d
V e rs u s B a tte ry V o lta g e in L o w P o w e r M o d e
3.0
3.5
4.0
4.5
5.0
5.5
0
V B AT= 5,5V
V B AT= 4,25V
-10
P S R R [d B ]
P S R R [d B ]
-20
-30
-40
freq= 1K Hz
-60
B a tte ry V o lta g e [V ]
F re q [H z ]
L D O S ta rtu p a t F u ll L o a d fo r V b a t = 4 .2 5 V in L o w
O u tp u t N o is e S p e c tru m a t F u ll L o a d a n d
P ow er M ode
V b a t=4 .2 5 V
1.0E -08
V B AT2 A
µ # $
O u tp u t N o ise [V ^ 2/H z ]
V o lta g e [V ]
freq= 100K Hz
freq= 100Hz
-50
V B AT= 3V
freq= 20K Hz
V S AU V
1.0E -09
1.0E -10
1.0E -11
1.0E -12
1.0E -13
1.0E -14
10
100
1000
10000
100000
F re q [H z ]
T im e [µs]
6
RE031 2.5V 5 mA LDO Voltage Regulator
2707B–PMGMT–03/03
RE031 2.5V 5 mA LDO Voltage Regulator
Terminology
Line Regulation
Measures the maximum transient and DC variations of the output voltage of the LDO
when the supply changes between two specified values with fixed load current; minimum rise time and fall time is 5 µs.
Figure 4. Line Regulation
3.4V
VBAT2A
3V
5 µs
5 µs
VSAUV
∆VTRAN
∆VDC
Load Regulation
Measures the maximum transient and DC variations of the output voltage of the LDO
when the load current changes between two specified values with fixed power supply;
minimum rise time and fall time is 5 µs.
Figure 5. Load Regulation
5 µs
5 µs
90% of max ISAUV
ISAUV
10% of max ISAUV
VSAUV
∆VTRAN
∆VDC
7
2707B–PMGMT–03/03
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2707B–PMGMT–03/03
0M