ZETEX ZXCT1010E5

ZXCT1010
ENHANCED HIGH-SIDE CURRENT MONITOR
DESCRIPTION
The ZXCT1010 is a high side current sense monitor.
Using this device eliminates the need to disrupt the
ground plane when sensing a load current.
APPLICATIONS
•
Battery Chargers
•
Smart Battery Packs
•
DC Motor control
It is an enhanced version of the ZXCT1009 offering
reduced typical output offset and improved accuracy
at low sense voltage.
•
Over current monitor
•
Power Management
•
Level translating
The wide input voltage range of 20V down to as low as
2.5V make it suitable for a range of applications. A
minimum operating current of just 4µA, combined
with its SOT23-5 package make suitable for portable
battery equipment.
•
Programmable current source
FEATURES
Vin
•
Low cost, accurate high-side current sensing.
•
Output voltage scaling.
•
Up to 2.5V sense voltage.
•
2.5V – 20V supply range.
•
300nA typical offset current.
•
4µA quiescent current.
•
1% typical accuracy.
•
SOT23 -5 package.
APPLICATION CIRCUIT
To Load
Rsense
Vin
Load
ZXCT1010
GND
I out
Vout
Rout
ORDERING INFORMATION
ISSUE 4 - DECEMBER 2001
1
PART NUMBER
PACKAGE
PARTMARKING
ZXCT1010E5
SOT23-5
1010
ZXCT1010
ABSOLUTE MAXIMUM RATINGS
Voltage on any pin
Continuous output current
Continuous sense voltage
Operating Temperature
Storage Temperature
Package Power Dissipation
SOT23-5
-0.6V to 20V (relative to GND)
25mA
Vin + 0.5V > Vsense†> Vin – 5V
-40 to 85°C
-55 to 125°C
(TA = 25°C)
500mW
ELECTRICAL CHARACTERISTICS
Test Conditions TA = 25°C, Vin = 5V, Rout = 100Ω.
SYMBOL
PARAMETER
CONDITIONS
LIMITS
Min
V in
V CC Range
I out 1
Output current
Iq
Ground pin current
V sense 2
Sense Voltage
I sense
Load pin
UNIT
Typ
2.5
Max
20
V
V sense = 0V
0
0.3
10
µA
V sense = 10mV
85
100
115
µA
V sense = 100mV
0.975
1.00
1.025
mA
V sense = 200mV
1.95
2.00
2.05
mA
V sense = 1V
9.7
10.0
10.3
mA
V sense = 0V
1
4
8
µA
0
2500
mV
100
nA
input current
Acc
Accuracy
Gm
Transconductance,
BW
Bandwidth
R sense = 0.1Ω
-2.5
V sense = 200mV
2.5
%
10000
µA/V
RF P in = -20dBm 3
V sense = 10mV dc
300
kHz
V sense = 100mV dc
2
MHz
I out / V sense
1
Includes input offset voltage contribution
Vsense=Vin-Vload
3
-20dBm=63mVp-p into 50Ω
2
ISSUE 4 - DECEMBER 2001
2
ZXCT1010
TYPICAL CHARACTERISTICS
ISSUE 4 - DECEMBER 2001
3
ZXCT1010
PIN DESCRIPTION
Pin Name
Pin Function
V in
Supply Voltage
Load
Connection to load/battery
I out
Output current, proportional to V in -V load
GND
Ground
CONNECTION DIAGRAM
SOT23-5
Package Suffix – E5
NC
1
GND
2
Iout
3
5
Load
4
VIN
Top View
SCHEMATIC DIAGRAM
Vin
Load
100Ω
+
-
Iout
ISSUE 4 - DECEMBER 2001
4
ZXCT1010
POWER DISSIPATION
APPLICATIONS INFORMATION
The maximum allowable power dissipation of the
device for normal operation (Pmax), is a function of
the package junction to ambient thermal resistance
(θja), maximum junction temperature (Tjmax), and
ambient temperature (Tamb), according to the
expression:
The following lines describe how to scale a load
current to an output voltage.
Vsense = Vin - Vload
Vout = 0.01 x Vsense x Rout1
Pmax = (Tjmax – Tamb) / θja
E.g.
The device power dissipation, PD is given by the
expression:
A 1A current is to be represented by a 100mV output
voltage:
PD=Iout.(Vin-Vout) Watts
1)Choose the value of Rsense to give 50mV > Vsense >
500mV at full load.
For example Vsense = 100mV at 1.0A. Rsense = 0.1/1.0
=> 0.1 ohms.
2)Choose Rout to give Vout = 100mV, when Vsense =
100mV.
Rearranging 1 for Rout gives:
Rout = Vout /(Vsense x 0.01)
Rout = 0.1 / (0.1 x 0.01) = 100 Ω
TYPICAL CIRCUIT APPLICATION
Vin
Rsense
V in
Load
ZXCT1010
GND
I out
Vout
Rload
Rout
Where Rload represents any load including DC motors,
a charging battery or further circuitry that requires
monitoring, R sense can be selected on specific
requirements of accuracy, size and power rating.
ISSUE 4 - DECEMBER 2001
5
ZXCT1010
Bi-Directional Current Sensing
APPLICATIONS INFORMATION (Continued)
FZT789A 140µH
1kΩ
3
BC81725
To Battery +
0.2Ω
ZHCS1000
Vin
Iout
Charger Input
The ZXCT1010 can be used to measure current
bi-directionally, if two devices are connected as
shown below.
Load
100Ω
BAS16
5
Load
Vin
4
10µH
+ -
5V
MOD pin
V1
V2
R sense
ZXCT1010
FMMT451
220Ω
4
Iout
Vin
Load
5
Vout
3
SNS pin
Iout
bq2954
100Ω
support components omitted for clarity
R out
Li-Ion Charger Circuit
The above figure shows the ZXCT1010 supporting
the Benchmarq bq2954 Charge Management IC.
Most of the support components for the bq2954 are
omitted for clarity. This design also uses the Zetex
FZT789A high current Super-␤ PNP as the switching
transistor in the DC-DC step down converter and the
FMMT451 as the drive NPN for the FZT789A. The
circuit can be configured to charge up to four Li-Ion
cells at a charge current of 1.25A. Charge can be
terminated on maximum voltage, selectable
minimum current, or maximum time out. Switching
frequency of the PWM loop is approximately 120kHz.
If the voltage V1 is positive with respect to the
voltage V2 the lower device will be active, delivering
a proportional output current to Rout. Due to the
polarity of the voltage across Rsense, the upper
device will be inactive and will not contribute to the
current delivered to Rout. When V2 is more positive
than V1, current will be flowing in the opposite
direction, causing the upper device to be active
instead.
Non-linearity will be apparent at small values of
Vsense due to offset current contribution. Devices
can use separate output resistors if the current
direction is to be monitored independently.
Bi-directional Transfer Function
Output Current (mA)
5
4
3
2
1
0
-400
-200
0
200
400
Sense Voltage (mV)
Output Current v Sense Voltage
ISSUE 4 - DECEMBER 2001
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ZXCT1010
APPLICATIONS INFORMATION (Continued)
PCB trace shunt resistor for low cost
solution.
The figure below shows output characteristics of the
device when using a PCB resistive trace for a low
cost solution in replacement for a conventional
shunt resistor. The graph shows the linear rise in
voltage across the resistor due to the PTC of the
material and demonstrates how this rise in
resistance value over temperature compensates for
the NTC of the device.
The figure opposite shows a PCB layout suggestion.
The resistor section is 25mm x 0.25mm giving
approximately 150mΩ using 1oz copper. The data
for the normalised graph was obtained using a 1A
load current and a 100Ω output resistor. An
electronic version of the PCB layout is available at
www.zetex.com/isense
Actual Size
Layout shows area of shunt
resistor compared to SOT23-5
package. Not actual size
ISSUE 4 - DECEMBER 2001
7
ZXCT1010
PACKAGE DIMENSIONS SOT23-5
DIM
Millimetres
Inches
MIN
MAX
MIN
MAX
A
0.90
1.45
0.035
0.057
A1
0.00
0.15
0.00
0.006
A2
0.90
1.3
0.035
0.051
b
0.35
0.50
0.014
0.020
C
0.09
0.20
0.0035
0.008
D
2.80
3.00
0.110
0.118
E
2.60
3.00
0.102
0.118
E1
1.50
1.75
0.059
0.069
e
0.95 REF
0.037 REF
e1
1.90 REF
0.075 REF
L
0.10
0.60
0.004
0.024
a°
0
10
0
10
© Zetex plc 2001
Zetex plc
Fields New Road
Chadderton
Oldham, OL9 8NP
United Kingdom
Telephone (44) 161 622 4422
Fax: (44) 161 622 4420
Zetex GmbH
Streitfeldstraße 19
D-81673 München
Zetex Inc
700 Veterans Memorial Hwy
Hauppauge, NY11788
Germany
Telefon: (49) 89 45 49 49 0
Fax: (49) 89 45 49 49 49
USA
Telephone: (631) 360 2222
Fax: (631) 360 8222
Zetex (Asia) Ltd
3701-04 Metroplaza, Tower 1
Hing Fong Road
Kwai Fong
Hong Kong
Telephone: (852) 26100 611
Fax: (852) 24250 494
These offices are supported by agents and distributors in major countries world-wide.
This publication is 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. The Company
reserves the right to alter without notice the specification, design, price or conditions of supply of any product or service.
For the latest product information, log on to
www.zetex.com
ISSUE 4 - DECEMBER 2001
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