TS12001 0.65V/1µA Nanopower Voltage Detector with Dual Outputs

TS12001
A 0.65V/1µA Nanopower Voltage Detector with Dual Outputs
FEATURES
DESCRIPTION
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Nanopower Voltage Detector in Single 4 mm2
Package
Ultra Low Total Supply Current: 1µA (max)
Supply Voltage Operation: 0.65V to 2.5V
Preset 0.78V UVLO Trip Threshold
Internal ±10mV Hysteresis
Resettable Latched Comparator
Complimentary and Open-drain Comparator
Outputs
Separate Comparator Output Supply Pin
APPLICATIONS
Power-Fail Indicator
Low-Battery Detection
Battery-Backup Detection
CPU, Microprocessor, and Logic Reset Controller
Battery-powered Systems
The TS12001 voltage detector combines a 0.58V
reference and a comparator with resettable
comparator latch in a single package. The TS12001
operates from a single 0.65V to 2.5V power supply
and consumes less than 1µA total supply current.
Optimized for ultra-long life operation, the TS12001
expands the growing “NanoWatt Analog™” highperformance analog integrated circuits portfolio.
The voltage detector exhibits a preset UVLO
threshold voltage of 0.78V (typ) or can be set to other
threshold voltages with two external resistors. The
comparator exhibits ±10mV of internal hysteresis for
clean, chatter-free output switching. The TS12001
also offers both push-pull and open-drain outputs.
When compared against similar products, the
TS12001 offers a factor-of-2 lower power
consumption and at least a 33% reduction in pcb
area.
The TS12001 is fully specified over the -40°C to
+85°C temperature range and is available in a lowprofile, 10-pin 2x2mm TDFN package with an
exposed back-side paddle.
TYPICAL APPLICATION CIRCUIT
A Nanopower 1.8V Core System Voltage Detector
Page 1
© 2014 Silicon Laboratories, Inc. All rights reserved.
TS12001
ABSOLUTE MAXIMUM RATINGS
Output Current
COUTPP, COUTOD………...…………................................20mA
Short-Circuit Duration
(REFOUT, COUTPP, COUTOD)………...………...….Continuous
Continuous Power Dissipation (TA = +70°C)
10-Pin TDFN (Derate at 13.48mW/°C above +70°C) ......... 1078mW
Operating Temperature Range ................................. -40°C to +85°C
Junction Temperature……………………………………..……+150°C
Storage Temperature Range .................................. -65°C to +150°C
Lead Temperature (Soldering, 10s)...................................... +300°C
Supply Voltage (VIN to VSS) ...................................................+2.75V
Supply Voltage (OVDD to VSS) ................................................+2.75V
Input Voltage
SET………………...…………………...….VSS – 0.3V to VIN + 0.3V
LHDET………………………………….…........VSS - 0.3V to +5.5V
Output Voltage
REFOUT……….…………………...…... VSS – 0.3V to VIN + 0.3V
COUTPP……………..……….........… VSS - 0.3V to OVDD + 0.3V
COUTOD……………………..…..………..… VSS - 0.3V to +5.5V
Electrical and thermal 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 condition beyond those indicated in the operational sections
of the specifications is not implied. Exposure to any absolute maximum rating conditions for extended periods may affect device reliability and
lifetime.
PACKAGE/ORDERING INFORMATION
ORDER NUMBER
PART
CARRIER QUANTITY
MARKING
TS12001ITD1022
Tape
& Reel
-----
Tape
& Reel
3000
AAN
TS12001ITD1022T
Lead-free Program: Silicon Labs supplies only lead-free packaging.
Consult Silicon Labs for products specified with wider operating temperature ranges.
Page 2
TS12001 Rev. 1.0
TS12001
ELECTRICAL CHARACTERISTICS
VIN = OVDD = 0.8V; VSS = 0V; VSET = VSS; VCOUTPP = HiZ; VCOUTOD = HiZ; TA = -40°C to +85°C, unless otherwise noted. Typical values are at
TA = +25°C. See note 1.
PARAMETER
SYMBOL CONDITIONS
MIN
TYP
MAX
UNITS
Supply Voltage
VIN
0.65
2.5
V
0.8
TA = +25°C
µA
Supply Current
IIN
REFOUT = open
-40°C ≤ TA ≤ 85°C
1
UVLO Output
Driver Supply
OVDD
0.65
2.5
V
Voltage
Output Driver
0.1
µA
IODD
Supply Current
falling
until
COUTPP
switches
LOW
725
761
797
V
Preset UVLO
IN
mV
Trip Point
VIN rising until COUTPP switches HIGH
743
781
818
540
567
595
TA = +25°C
VSET falling until COUTPP switches LOW
-40°C ≤ TA ≤ 85°C
534
604
SET Trip Point
560
587
615
TA = +25°C
VSET rising until COUTPP switches HIGH
-40°C ≤ TA ≤ 85°C
550
620
13
VSET rising
SET Trip
µs
Response Time
VSET falling
10
Preset UVLO
±10
mV
Trip Hysteresis
SET Enable
See Note 2
90
mV
Threshold
SET Input
20
nA
VSET = VSS; VSET = VIN
Leakage
0.1
0.78V ≤ VIN ≤ 1.1V
Comparator Latched Output
LHDET Input
V
VIL
Enabled
Low Voltage
1.1V < VIN ≤ 2.5V
0.2
VIN -0.1
0.78V ≤ VIN ≤ 1.1V
Comparator Latched Output
LHDET Input
V
VIH
Disabled
1.1V < VIN ≤ 2.5V
1
High Voltage
LHDET Input
100
nA
VLHDET = VSS; VLHDET = 5.5V
Leakage
555
577
600
TA = +25°C
Reference
mV
VREF
Output Voltage
-40°C ≤ TA ≤ 85°C
552
602
Reference
0.5
%
Load
IOUT = ±100nA
Regulation
Output High
VOH
COUTPP; IOUT = -100μA
VIN – 0.1
V
Voltage
Output Low
COUTPP; IOUT = 100μA
VSS + 0.1
V
VOL
Voltage
Output Low
COUTOD; IOUT = 100μA
VSS + 0.11
V
VOL
Voltage
0.1
mA
Sourcing; VCOUTPP = VSS
Output ShortCircuit
ISC
Sinking; VCOUTPP = VIN
0.5
mA
Current,
Sinking; VCOUTOD = VIN
1.4
mA
Open Drain
COUTOD; VCOUTOD = 5V
20
nA
Leakage
Note 1: All devices are 100% production tested at TA = +25°C and are guaranteed by characterization for TA = TMIN to TMAX, as specified.
Note 2: A SET voltage above this threshold voltage enables the SET pin voltage to control the comparator output.
TS12001 Rev. 1.0
Page 3
TS12001
TYPICAL PERFORMANCE CHARACTERISTICS
VIN = OVDD = 2.5V; VSS = 0V; VSET = VSS; VCOUTPP = HiZ; VCOUTOD = HiZ, unless otherwise noted. Typical values are at TA = +25°C.
Supply Current
vs Supply Voltage and Temperature
Reference Voltage vs Temperature
0.592
REFERENCE VOLTAGE - V
SUPPLY CURRENT - µA
0.8
TA = +85ºC
0.7
TA = +25ºC
0.6
TA = -40ºC
0.5
0.4
0.588
0.586
0.584
0.582
0.65 1.02
1.39
1.76
2.13
-15
-40
2.5
60
SET Threshold Voltage
vs Temperature
COUTPP Output Voltage High
vs Source Current
0.6
85
0.5
Low-to-High
VIN - VOH - V
0.59
0.585
0.4
0.3
0.2
High-to-Low
0.58
0.1
0
0.575
-40
-15
10
35
60
85
0
1
TEMPERATURE - ºC
2
3
4
SOURCE CURRENT - mA
COUTPP Output Voltage Low
vs Sink Current
COUTOD Short-Circuit Current
vs Supply Voltage
0.4
SHORT-CIRCUIT CURRENT - mA
2.5
0.3
VOL - V
35
TEMPERATURE - ºC
0.595
0.2
0.1
0
VCOUTOD = VIN
2
1.5
1
0.5
0
1
2
SINK CURRENT - mA
Page 4
10
SUPPLY VOLTAGE - Volt
0.6
SET THRESHOLD VOLTAGE - V
0.59
3
0.65
1.11
1.58
2.04
2.5
SUPPLY VOLTAGE - V
TS12001 Rev. 1.0
TS12001
TYPICAL PERFORMANCE CHARACTERISTICS
VIN = OVDD = 2.5V; VSS = 0V; VSET = VSS; VCOUTPP = HiZ; VCOUTOD = HiZ, unless otherwise noted. Typical values are at TA = +25°C.
COUTPP Short-Circuit Current
vs Supply Voltage
COUTPP Short-Circuit Current
vs Supply Voltage
18
SHORT-CIRCUIT CURRENT - mA
SHORT-CIRCUIT CURRENT - mA
16
VCOUTPP = VSS
12
8
4
0
VCOUTPP = VIN
12
6
0
0.65
1.11
1.58
2.04
0.65
2.5
1.58
2.04
2.5
SUPPLY VOLTAGE - V
SUPPLY VOLTAGE - V
COUTPP Transient Response with LHDET
VIN = OVDD = 2.5V, CLOAD = 15pF
OUTPUT
1V/DIV
VIN
1V/DIV
COUTPP LHDET
SET
2V/DIV 2V/DIV 500mV/DIV
COUTPP Power-Up Transient Response
VSET = 2.5V, CLOAD = 15pF
100ms/DIV
TS12001 Rev. 1.0
1.11
500µs/DIV
Page 5
TS12001
PIN FUNCTIONS
Page 6
PIN
NAME
1
VIN
2
SET
3
4
NC
VSS
5
LHDET
6
7
8
9
REFOUT
NC
COUTOD
COUTPP
10
OVDD
EP
----
FUNCTION
Positive Supply Voltage. Connect a 0.1µF bypass capacitor from
this pin to analog VSS/GND.
External UVLO Trip Threshold Set Pin. When this pin is set to
VSS, the internal preset 0.78V UVLO trip threshold controls the
comparator output. When the applied voltage to this pin is higher
than 90mV, the SET pin sets the trip threshold and controls the
comparator output. If the SET pin is not used, connect the pin to
to VSS.
No Connection
Negative Supply Voltage.
Latch Enable Pin. When LHDET is set HIGH, the outputs of the
comparator will toggle normally based on the inputs to the
comparator. When LHDET is set LOW and COUTPP is HIGH,
COUTPP will remain HIGH despite any changes to the input of
the comparator. COUTPP will once again respond to changes to
the input when LHDET is toggled HIGH. If COUTPP is initially
LOW and the LHDET is then LOW, COUTPP will stay LOW. If a
LOW-to-HIGH transition occurs on COUTPP, COUTPP will
switch to HIGH and stay HIGH and not respond to any changes
at the input. The LHDET pin must always be set to a known state.
For unlatched comparator operation, set LHDET to HIGH. The
open-drain output (COUTOD) is the inverted version of the
COUTPP output.
0.58V Reference Output
No Connection
Comparator Open-Drain Output
Comparator Push-Pull Output
Output Driver Positive Supply Voltage. Connect a 0.1µF bypass
capacitor from this pin to analog VSS/GND.
Exposed paddle is electrically connected to VSS/GND.
TS12001 Rev. 1.0
TS12001
BLOCK DIAGRAM
THEORY OF OPERATION
The TS12001 combines a 0.58V ±4.5% reference
and an analog comparator with a resettable
comparator latch in a single package. The TS12001
operates from a single 0.65V to 2.5V power supply
and consumes less than 1µA total supply current.
The TS12001 comparator has a push-pull and opendrain output driver. The push-pull output driver is
powered from a separate supply voltage, OVDD. The
open-drain output stage allows for easy output
voltage level translation as may be required when
driving systems powered with a different power
supply rail. The analog comparator exhibits ±10mV of
internal hysteresis for clean, chatter-free output
switching. The internal reference was designed to
sink or source up to 0.1µA load currents.
The TS12001 has a preset UVLO threshold voltage
of 0.78V (typ) or can be set to other threshold
voltages with two external resistors where the divided
TS12001 Rev. 1.0
voltage is applied to the SET pin. When the SET pin
voltage is grounded or it is less than approximately
90mV, the internal preset UVLO threshold circuit will
control the comparator outputs. If the SET pin is
above approximately 90mV, the external voltage
divider circuit will control the comparator outputs. The
0.58V reference voltage is tied to the inverting input
of the comparator and the output of a switch is
connected to the non-inverting input of the
comparator. The output of the switch is either the
SET voltage or the internal UVLO threshold voltage,
depending on whether the SET pin voltage is above
or below approximately 90mV. If the switch output is
above 0.58V, the push-pull output (COUTPP) will be
HIGH and the open-drain output (COUTOD) will be
LOW and vice versa. For proper operation, the
supply voltage VIN must be applied before the output
driver supply voltage (OVDD) is applied.
The TS12001 has a latch enable pin (LHDET) that
Page 7
TS12001
allows the output of the comparator to latch to a
HIGH state under certain conditions. If LHDET is set
HIGH, the COUTPP output will switch based on the
input to the comparator. When LHDET is set LOW
and COUTPP is HIGH, COUTPP will remain HIGH
until LHDET goes HIGH. If COUTPP is initially LOW
instead, COUTPP will remain LOW until a LOW-toHIGH transition occurs on the COUTPP output. After
this event, COUTPP will remain HIGH and be
unresponsive to any changes at the input of the
comparator until LHDET goes HIGH. In essence, the
LHDET pin offers a LOW-to-HIGH detection.
However, LHDET must not be left open. The opendrain output, COUTOD, is the inverter version of the
COUTPP output. Connect LHDET to VIN for normal
operation or to VSS for LHDET enable.
If the SET pin is not used, it cannot be left
unconnected and should be tied to VSS.
Comparator
The TS12001 has an internal comparator that can
eliminate supply glitches that commonly occur when
APPLICATIONS INFORMATION
External Voltage Detector Design
Depending on the battery voltage used and the
voltage one wishes to detect, the TS12001 can be
designed accordingly. As shown in Figure 1, R1 and
R2 can be selected based on the desired voltage to
detect. Table 1. provides R1 and R2 resistor
combinations for detecting various VIN voltages.
VIN Threshold
R1(MΩ) R2(MΩ)
Voltage(V)
0.9
2.2
4.02
1.07
3.32
4.02
1.28
4.75
4.02
1.52
6.49
4.02
1.85
8.66
4.02
Table 1. Resistor Combinations for Several VIN
Threshold Voltages
The design equation for this circuit is shown
below. The SET pin voltage (VSET) that will
cause a HIGH-to-LOW transition on the output is
approximately 580mV. To design the circuit, R1
Page 8
output transitions occur. In addition, the input exhibits
±10mV of internal hysteresis in order to insure clean
output switching behavior. The outputs can swing to
within 100mV of the supply rails. The COUTPP
output can source and sink 0.1mA and 0.5mA of
current. The COUTD outputs can sink 1.4mA of
current with VCOUTOD = 0.78V
Internal Reference
The TS12001’s on-board 0.58V ±4.5% reference
voltage can source and sink 0.1µA and 0.1µA of
current and can drive a capacitive load less than
50pF and greater than 50nF with a maximum
capacitive load of 250nF. The higher the capacitive
load, the lower the noise on the reference voltage
and the longer the time needed for the reference
voltage to respond and become available on the
REFOUT pin. With a 250nF capacitive load, the
response time is approximately 20ms. While also
available as a separate pin as REFOUT, the
reference is tied internally to the inverting input of the
comparator.
or R2 can be selected along with the desired
battery voltage to detect.
Then, the second resistor value can be
evaluated using the voltage divider equation
below.
R1=
VIN x R2‐VSET x R2
VSET
A Nanopower 1.8V Core System Voltage Detector
When power supply rails sag in any system, it is
important to alert the CPU. A CPU can be used to
detect when I/O or core system voltages sag below a
prescribed threshold as shown Figure 2. In this
circuit, a 1.8V core system voltage detector is
designed around the TS12001 providing a low battery
detect signal. R1 and R2 were selected to set a SET
voltage at 582mV so that when VCORE drops below
1.77V, the TS12001 output transitions to LOW. It is
recommended to use 1% resistors for optimal
accuracy. The circuit consumes approximately
0.75µA of current when VCORE = 1.8V.
PC Board Layout and Power-Supply Bypassing
While power-supply bypass capacitors are not
typically required, it is good engineering practice to
use 0.1uF bypass capacitors close to the device’s
TS12001 Rev. 1.0
TS12001
power supply pins. When the power supply
impedance is high, the power supply leads are long,
or there is excessive noise on the power supply
traces. To reduce stray capacitance, it is also good
engineering practice to make signal trace lengths as
short as possible. Also recommended are a ground
plane and surface mount resistors and capacitors.
Input Noise
Radiated noise is common in low power circuits that
require high impedance circuits. To minimize this
effect, all traces between any of the inputs and
passive component networks should be made as
short as possible.
Figure 1. External Voltage Detector Design Circuit
Figure 2. A Nanopower 1.8V Core System Voltage Detector Circuit
TS12001 Rev. 1.0
Page 9
TS12001
PACKAGE OUTLINE DRAWING
10-Pin TDFN22 Package Outline Drawing
(N.B., Drawings are not to scale)
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TS12001 Rev. 1.0
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