DIODES ZXCT1012

ZXCT1012
Reduced height micro-power current monitor
Description
The ZXCT1012 is a high side current sense
monitor. Using this type of device eliminates
the need to disrupt the ground plane when
sensing a load current.
A minimum operating current of just 3.5µA,
combined with its TSOT23-5 package make it
suitable for portable battery equipment where
size and current consumption are critical.
The ZXCT1012 takes the voltage developed
across a small value resistor and translates it
into a proportional output current. A user
defined output resistor scales the output
current into a ground referenced voltage.
The wide input voltage range down to as low as
2.5V make it suitable for a wide range of
applications requiring direct operation from a
battery.
The ZXCT1012 has the accuracy specification of
the ZXCT1010 but in TSOT23-5, and TDFN3x3-5.
Features
Applications
•
2.5V to 20V supply range
•
Battery fuel gauge
•
3.5µA quiescent current
•
Battery chargers
•
Current output - user set gain
•
Overcurrent monitor
•
Thin package - TSOT23-5 and TDFN3x3-5
•
Power management
•
Temperature range -40 to 85°C
Pin connections
Applications circuit
SENSE-
SENSE
IN
SENSE+
OUT
SENSE+
TSOT23-5
Pinout - top view
SENSE-
ZXCT1012
OUT
NC
3
GND
2
OUT
1
4
LOAD
SENSEOUT
5
OUT
SENSE+
TDFN3x3-5
Pinout - bottom view
Ordering information
Device
Package
Status
Device
marking
ZXCT1012DAATA TDFN-5 (3mm x 3mm)
Active
1012
7
8
3000
ZXCT1012ET5TA
Active
1012
7
8
3000
TSOT23-5
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Reel size Tape width
(inches)
(mm)
Quantity
per reel
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ZXCT1012
Pin information
Pin
Name
Description
TDFN5 TSOT23-5
3
1
N/C
No connection
2
2
GND
Ground connection
1
3
OUT
Output current pin. Current generated due to a difference voltage
between VSENSE+ and VSENSE- flows out of this pin. A suitable
value resistor connected to ground creates an output voltage. The
maximum voltage out of this pin will be VSENSE- - 1.5V.
5
4
SENSE+ This pin should be connected to the rail whose current is being
measured and also provides power to internal circuitry. It is the
positive input of the current monitor and has an input range from
20V down to 2.5V. The current through this pin varies with
differential sense voltage.
4
5
SENSE- This is the negative input of the current monitor and has an input
range from 20V down to 2.5V.
Absolute maximum ratings
VSENSE+ max.
20V
Voltage on any pin (relative to GND pin)
-0.6 and VSENSE+ +0.5V
VSENSE(‡)
-0.15V to +3V
Ambient operating temperature range
-40 to 85°C
Storage temperature
-55 to 150°C
Maximimum junction temperature
150°C
Package power dissipation
300mW at Tamb= 25°C (De-rate to zero at 150°C)
R⍜JA
PDISS at 25°C
TSOT23-5 (*)
250°C/W
500mW
TDFN3x3 5 pin(*) (†)
232°C/W
540mW
Package
NOTES:
(*) Mounted on 30mm x 16mm x1.1mm FR4 board with 1oz copper.
Operation above the absolute maximum rating may cause device failure.
Operation at the absolute maximum ratings, for extended periods, may reduce device reliability.
NOTES:
(‡) VSENSE is defined as the differential voltage between the SENSE+ and SENSE- pins.
VSENSE = VSENSE+ - VSENSE(†) Exposed lead not connected to thermal plane
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ZXCT1012
Recommended operating conditions
Symbol
Recommended parameter
Min.
2.5
Limits
Max.
20
VIN
Sense+ range
Units
V
TA
Ambient temperature range differential
-40
85
°C
VSENSE
Sense voltage
10
2500
mV
VOUT
Output voltage swing
0
VSENSE- -1.5
V
Electrical characteristics
Test conditions Tamb = 25°C, VIN = VSENSE+ = 5V, unless otherwise stated
Symbol Parameter
Conditions
IOUT
VSENSE = 0V
Output current
Min.
0
Limits
Typ.
0.3
Max.
15
␮A
VSENSE = 10mV
85
100
115
␮A
VSENSE = 40mV
380
400
420
␮A
VSENSE = 100mV
0.975
1.00
1.025 mA
VSENSE = 200mV
1.95
2.00
2.05
mA
3.5
8
␮A
100
nA
2.5
%
IQ
Ground pin current VSENSE = 0V
ISENSE-
SENSE- pin input
current
Accuracy
Acc
RSENSE = 0.1V
VSENSE = 200mV
-2.5
Gm
Transconductance,
IOUT/VSENSE(*)
Tc
Temperature
coefficient
VSENSE = 200mV
Tamb = 0 to 50°C
(*)
Bandwidth
CL = 5pF,
ROUT = 1k⍀
VSENSE = 10mV
VSENSE = 100mV
BW
CMRR(‡) Common mode
rejection ratio
VSENSE = 100mV, ROUT = 1k⍀
VIN = 2.5V to 20V
Unit
10
mA/V
500
ppm/
°C
300
2
kHz
MHz
80
dB
NOTES:
(*) Temperature dependent measurements are extracted from characterisation and simulation results.
(‡) With the ZXCT1012 using SENSE+ as its power supply pin, common mode rejection cannot be distinguished from
power supply rejection.
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ZXCT1012
Typical characteristics
2%
0%
-2%
-4%
-6%
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ZXCT1012
Applications information
The ZXCT1012 current monitor works by converting the voltage developed across a small sense
resistor into a current on the out pin. In reality it is a voltage to current converter. This output
current can be converted into a voltage simply by passing it through a resistor (ROUT) to ground.
The current monitor has a transconductance of 10mA/V. But the overall amplifying conversion is
affected by both the RSENSE and ROUT.
The gain equation of the ZXCT1012 is:
R OUT
V OUT = I L × R SENSE --------------100
For best performance RSENSE should be connected as close to the SENSE+ (and SENSE-) pins;
which minimizes any series resistance with RSENSE and potential for interference pickup.
When choosing appropriate values for RSENSE a compromise must be reached between in-line
signal loss (including potential power dissipation effects) and small signal accuracy.
Higher values for RSENSE gives better accuracy at low load currents by reducing the inaccuracies
due to internal offsets. For best operation the ZXCT1012 has been designed to provide best
performance with VSENSE of the order of 40mV to 200mV.
Current monitors are single supply devices which means they tend to saturate at very low sense
voltages. However it does mean the output can never go negative. Also the output can never
change direction (monotonic). This is important if the current monitor is used in a control loop.
As the sense voltage is reduced the output will tend to saturate as the input offset voltage starts
to have greater effect. It is recommended to have a minimum sense voltage of 10mV to minimize
linearity errors. Zetex has specified the output voltage at VSENSE of 10mV, 40mV, 100mV and
200mV; which is the recommended sense voltage range.
The maximum differential input voltage, VSENSE, is 2.5V; however this will cause large output
currents to flow increasing power dissipation in the chip. The sense voltage can be increased
further, without damaging the ZXCT1012, by the inclusion of a resistor, RLIM, between SENSE- pin
and the load. Typical values around 10k⍀. See figure below.
SENSE
RLIM
CC
ZXCT1012
If large reverse currents are expected then the resistor, RLIM, will provide protection from
exceeding absolute maximum ratings.
A suitable value for RLIM can be determined from:
V SENSE ( REF )
R LIM » ---------------------------------5mA
Where VSENSE(REV) is the maximum expected reverse sense voltage generated.
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ZXCT1012
The following lines describe how to scale a load current to an output voltage.
VSENSE
= RSENSE * ILOAD
equation (1)
IOUT
= 10mA/V x VSENSE
equation (2)
VOUT
= IOUT x ROUT
equation (3)
Design example
In the circuit below a 1A current is to be represented by a 100mV output voltage (VOUT):
A) To be within recommended values choose the value of RSENSE to give:
50mV > VSENSE > 200mV at full load.
For example set VSENSE = 100mV at 1.0A.
From equation (1)
RSENSE
= 0.1V/1.0A
= 0.1⍀
B) Now choose ROUT to give:
VOUT = 100mV, when VSENSE = 100mV.
From equation (2)
IOUT
= 10mA/V x 0.1
= 1mA
Rearranging equation (3) for ROUT gives:
ROUT = VOUT/IOUT
= 0.1/0.001
= 100⍀
SENSE
IN
SENSE+
SENSE-
ZXCT1012
GND
OUT
LOAD
OUT
OUT
= 0.1 / (0.1 x 0.01) = 100⍀
Typical circuit application
Where RLOAD represents any load including DC motors, a charging battery or further circuitry that
requires monitoring, Rsense can be selected on specific requirements of accuracy, size and power
rating.
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ZXCT1012
Power dissipation
The maximum allowable power dissipation of the device for normal operation (PMAX), is a
function of the package junction to ambient thermal resistance (⍜JA), maximum junction
temperature (TJMAX), and ambient temperature (Tamb), according to the expression:
PMAX = (TJMAX – Tamb) / ⍜JA
The device power dissipation, PD is given by the expression:
PD=IOUT.(VIN-VOUT) watts
Care must be taken when using this device at large input voltages and large sense voltages to
prevent too much power dissipation.
Power Dissipation
600
PD - Power Dissipation
(mW)
TDFN3x3-5
500
TSOT23-5
400
300
200
100
0
0
25
50
75
100
125
150
TA - Ambient temperature (°C)
VIN
= 20V
ROUT
= 100⍀
IOUT
= 2.5 x 0.01
VSENSE = 2.5V
= 25mA
VOUT
= IOUT x ROUT
= 25mA x 100⍀
= 2.5V
∴ PD
= 25mA (20 - 2.5)V
= 438mW
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ZXCT1012
Package outline - TSOT23-5
DIM
A
A1
A2
b
c
D
E
E1
e
e1
L
L2
a°
Millimeters
Min.
0.01
0.84
0.30
0.12
Inches
Max.
1.00
0.10
0.90
0.45
0.20
Min.
0.0003
0.0330
0.0118
0.0047
2.90 BSC
2.80 BSC
1.60 BSC
0.95 BSC
1.90 BSC
0.30
0.114 BSC
0.110 BSC
0.062 BSC
0.0374 BSC
0.0748 BSC
0.50
0.0118
0.25 BSC
4°
Max.
0.0393
0.0039
0.0354
0.0177
0.0078
0.0196
0.010 BSC
12°
4°
12°
Note: Controlling dimensions are in millimeters. Approximate dimensions are provided in inches
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ZXCT1012
DAA package outline - TDFN3x3-5
K
b
e
D
D2
L
e
A3
D2/2
A
E
E2
E2/2
A1
Dim.
Millimeters
Inches
Dim.
Millimeters
Min.
Max.
Min.
Max.
A
0.70
0.80
0.0276
0.0315
e
0.95REF
0.0374REF
A1
0.00
0.05
0.00
0.002
E
3.00BSC
0.1181BSC
A3
b
D
D2
0.20REF
0.30
0.45
3.00BSC
1.85
2.10
Min.
0.0079REF
0.0118
0.0177
0.1181BSC
0.0728
0.0827
Max.
Inches
Max.
Max.
E2
0.85
1.10
0.0335
0.0433
L
0.30
0.50
0.0118
0.0197
K
0.20
-
0.0079
-
-
-
-
-
-
Note: Controlling dimensions are in millimeters. Approximate dimensions are provided in inches
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ZXCT1012
Definitions
Product change
Zetex Semiconductors reserves the right to alter, without notice, specifications, design, price or conditions of supply of any product or
service. Customers are solely responsible for obtaining the latest relevant information before placing orders.
Applications disclaimer
The circuits in this design/application note are offered as design ideas. It is the responsibility of the user to ensure that the circuit is fit for
the user’s application and meets with the user’s requirements. No representation or warranty is given and no liability whatsoever is
assumed by Zetex with respect to the accuracy or use of such information, or infringement of patents or other intellectual property rights
arising from such use or otherwise. Zetex does not assume any legal responsibility or will not be held legally liable (whether in contract,
tort (including negligence), breach of statutory duty, restriction or otherwise) for any damages, loss of profit, business, contract,
opportunity or consequential loss in the use of these circuit applications, under any circumstances.
Life support
Zetex products are specifically not authorized for use as critical components in life support devices or systems without the express written
approval of the Chief Executive Officer of Zetex Semiconductors plc. As used herein:
A. Life support devices or systems are devices or systems which:
1. are intended to implant into the body
or
2. support or sustain life and whose failure to perform when properly used in accordance with instructions for use provided in the
labelling can be reasonably expected to result in significant injury to the user.
B. A critical component is any component in a life support device or system whose failure to perform can be reasonably expected to
cause the failure of the life support device or to affect its safety or effectiveness.
Reproduction
The product specifications contained in this publication are issued to provide outline information only which (unless agreed by the
company in writing) may not be used, applied or reproduced for any purpose or form part of any order or contract or be regarded as a
representation relating to the products or services concerned.
Terms and Conditions
All products are sold subjects to Zetex’ terms and conditions of sale, and this disclaimer (save in the event of a conflict between the two
when the terms of the contract shall prevail) according to region, supplied at the time of order acknowledgement.
For the latest information on technology, delivery terms and conditions and prices, please contact your nearest Zetex sales office.
Quality of product
Zetex is an ISO 9001 and TS16949 certified semiconductor manufacturer.
To ensure quality of service and products we strongly advise the purchase of parts directly from Zetex Semiconductors or one of our
regionally authorized distributors. For a complete listing of authorized distributors please visit: www.zetex.com/salesnetwork
Zetex Semiconductors does not warrant or accept any liability whatsoever in respect of any parts purchased through unauthorized sales channels.
ESD (Electrostatic discharge)
Semiconductor devices are susceptible to damage by ESD. Suitable precautions should be taken when handling and transporting devices.
The possible damage to devices depends on the circumstances of the handling and transporting, and the nature of the device. The extent
of damage can vary from immediate functional or parametric malfunction to degradation of function or performance in use over time.
Devices suspected of being affected should be replaced.
Green compliance
Zetex Semiconductors is committed to environmental excellence in all aspects of its operations which includes meeting or exceeding
regulatory requirements with respect to the use of hazardous substances. Numerous successful programs have been implemented to
reduce the use of hazardous substances and/or emissions.
All Zetex components are compliant with the RoHS directive, and through this it is supporting its customers in their compliance with
WEEE and ELV directives.
Product status key:
“Preview”
Future device intended for production at some point. Samples may be available
“Active”
Product status recommended for new designs
“Last time buy (LTB)”
Device will be discontinued and last time buy period and delivery is in effect
“Not recommended for new designs” Device is still in production to support existing designs and production
“Obsolete”
Production has been discontinued
Datasheet status key:
“Draft version”
This term denotes a very early datasheet version and contains highly provisional information, which
may change in any manner without notice.
“Provisional version”
This term denotes a pre-release datasheet. It provides a clear indication of anticipated performance.
However, changes to the test conditions and specifications may occur, at any time and without notice.
“Issue”
This term denotes an issued datasheet containing finalized specifications. However, changes to
specifications may occur, at any time and without notice.
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USA
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Oldham, OL9 9LL
United Kingdom
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Fax: (1) 631 360 8222
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© 2006 Published by Zetex Semiconductors plc
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