ETC IL610-2ETR13 Passive input digital isolator Datasheet

IL610 IL611 IL612
IL613 IL614
Passive Input Digital Isolators
Functional Diagram
Features
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40 Mbps Data Rate
Very Wide Input Voltage Range
Open Drain or CMOS Outputs
Failsafe Output (Logic high output for zero coil current )
Output Enable
3.3 V or 5 V Power Supply
2500 VRMS Isolation (1 Minute)
Low Power Dissipation
-40°C to 85°C Temperature Range
20 kV/µs Typical Common Mode Rejection
UL1577 & IEC61010 Approval (pending)
Available in MSOP, SOIC, and PDIP Packages
and as Bare Die
Applications
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CAN Bus/ Device Net
General Purpose Opto Replacement
Wired-OR Alarms
SPI interface
I2C
RS 485, RS422, RS232
Digital Fieldbus
Size critical multi-channel applications
Description
The IL600 series are isolated signal couplers with CMOS or
open drain transistor outputs which can be used to replace
opto-couplers in many standard isolation functions. The
devices are manufactured with NVE’s patented IsoLoop®
GMR sensor technology giving exceptionally small size and
low power dissipation.
A single resistor is used to set maximum input current for
input voltages above 0.5 V. The devices are available in
SOIC, PDIP and MSOP packages and as bare die.
Isoloop® is a registered trademark of NVE Corporation.
*U.S. Patent number 5,831,426; 6,300,617 and others.
ISB-DS-001-IL612-A, January 20, 2005
NVE Corp., 11409 Valley View Road, Eden Prairie, MN 55344-3617, U.S.A.
Telephone: 952-829-9217, Fax 952-829-9189, www.isoloop.com
© 2005 NVE Corporation
IL610 IL611 IL612
IL613 IL614
Absolute Maximum Ratings(1)
Parameters
Storage Temperature
Ambient Operating Temperature
Supply Voltage
Input Current
Output Voltage
Maximum Output Current
ESD
Symbol
TS
TA
VDD
IIN
VO
IO
Min.
-55
-55
-0.5
-25
-0.5
-10
Typ.
Max.
150
125
7
25
VCC+0.5
10
Units
°C
°C
V
mA
V
mA
kV
Test Conditions
Test Conditions
6.5
4
50
400
Units
°C
V
mA
mA
V
V
mA
ms
VAC RMS
Max.
Units
Test Conditions
2
HBM
Recommended Operating Conditions
Parameters
Ambient Operating Temperature
Supply Voltage
Input Current
Output Current
Open Drain Reverse Voltage
Open Drain Voltage
Open Drain Load Current
Input Signal Rise and Fall Times
Common Mode Input Voltage
Symbol
TA
VDD
IIN
IOUT
VSD
VDS
IOD
tIR, tIF
VCM
Min.
-40
3.0
0
-4
-0.5
Symbol
Min.
Typ.
Max.
85
5.5
10
4
Insulation Specifications
Parameters
Creepage Distance (external)
MSOP
0.15’’ SOIC
0.30’’ SOIC
0.30’’ PDIP
Internal Isolation Distance
Leakage Current
Barrier Impedance
Typ.
3.010
4.026
8.077
7.077
mm
mm
mm
mm
µm
µARMS
Ω || pF
9
0.2
>1014||7
240 VRMS, 60 Hz
Safety & Approvals
IEC61010-1
TUV Certificate Numbers:
Approval Pending
Classification
Model
IL610-1, IL610A-1, IL611-1, IL611A-1
IL610-2, IL610A-2, IL611-2, IL611A-2, IL612-2, IL612A-2
IL613, IL614
IL610-3, IL610A-3, IL611-3, IL611A-3, IL612-3, IL612A-3
IL613-3, IL614-3
Package
MSOP
PDIP
SOIC (0.3")
SOIC (0.15")
Pollution
Degree
II
II
II
Material
Group
III
III
III
Max. Working
Voltage
100 VRMS
300 VRMS
300 VRMS
II
III
150 VRMS
UL 1577
Approval Pending
Component Recognition program. File #:
Rated 2500VRMS for 1 minute (SOIC, PDIP), 1000VRMS for 1 minute (MSOP)
Electrostatic Discharge Sensitivity
This product has been tested for electrostatic sensitivity to the limits stated in the specifications. However, NVE recommends that all integrated
circuits be handled with appropriate care to avoid damage. Damage caused by inappropriate handling or storage could range from performance
degradation to complete failure.
2
IL610 IL611 IL612
IL613 IL614
IL610 and IL610A Pin Connections
1
2
3
4
5
6
7
NC
IN+
INNC
GND
OUT
VOE
8
VDD
No internal connection
Coil connection
Coil connection
No internal connection
Ground return for VDD
Data out
Output enable. Internally held low with
100 kΩ
Supply Voltage
IL610
IL610A
IL611 and IL611A Pin Connections
1
2
3
4
5
6
7
8
IN1+
IN1IN2+
IN2GND
OUT2
OUT1
VDD
Channel 1 coil connection
Channel 1 coil connection
Channel 2 coil connection
Channel 2 coil connection
Ground return for VDD
Data out channel 2
Data out channel 1
Supply Voltage
IL611
IL611A
IL612 and IL612A Pin Connections
1
2
3
4
5
6
7
8
IN1
VDD 1
OUT2
GND1
GND2
IN2
VDD 2
OUT1
Data in, channel 1
Supply Voltage 1
Data out, channel 2
Ground return for VDD1
Ground return for VDD2
Data in, channel 2
Supply Voltage 2
Data out, channel 1
IL612
IL612A
IL613 Pin Connections
1
2
3
4
5
6
7
8
9
IN1+
*
IN1IN2+
IN2IN3+
IN3*
GND
10
11
12
OUT3
NC
VDD
13
14
15
OUT2
OUT1
GND
16
VDD
Channel 1 coil connection
Internally connected to pin 8
Channel 1 coil connection
Channel 2 coil connection
Channel 2 coil connection
Channel 3 coil connection
Channel 3 coil connection
Internally connected to pin 2
Ground return for VDD (Internally
connected to pin 15)
Data out channel 3
No connection
Supply Voltage. Pin 12 and pin 16 must be
connected externally
Data out channel 2
Data out channel 1
Ground return for VDD (Internally
connected to pin 9)
Supply Voltage. Pin 12 and pin 16 must be
connected externally
IL613
* Pins 2 and 8 internally connected
** Pins 9 and 15 internally connected
3
IL610 IL611 IL612
IL613 IL614
IL614 Pin Connections
1
2
VDD1
GND1
3
4
OUT1
RE
5
6
IN2
Vcoil
7
8
IN3
GND1
9
GND2
10
11
12
13
14
15
OUT3
NC
VDD2
OUT2
IN1+
GND2
16
IN1-
Supply Voltage 1
Ground return for VDD1 (Internally
connected to pin 8)
Data out channel 1
Channel 1 data output enable. Internally
held low with 100 kΩ
Data in channel 2
Supply connection for channel 2 and
channel 3 coils
Data in channel 3
Ground return for VDD1 (Internally
connected to pin 2)
Ground return for VDD2 (Internally
connected to pin 15)
Data out channel 3
No connection
Supply Voltage 2
Data out channel 2
Coil connection
Ground return for VDD2 (Internally
connected to pin 9)
Coil connection
IL614
* Pins 2 and 8 internally connected
** Pins 9 and 15 internally connected
4
IL610 IL611 IL612
IL613 IL614
Electrical Specifications
Electrical Specifications are Tmin to Tmax unless otherwise stated.
Parameters
Symbol
Min.
Coil Input Impedance
ZCOIL
47||8
Temperature Coeff of Coil Resistance
TC RCOIL
Input Threshold for Logic High
I INH
Input Threshold for Logic Low
I INL
10
Quiescent Current
IL610, IDD1
IL610, IDD2
IL611, IDD1
IL611, IDD2
IL612, IDD1
IL612, IDD2
IL613, IDD1
IL613, IDD2
IL614, IDD1
IL614, IDD2
Quiescent Current
IL610, IDD1
IL610, IDD2
IL611, IDD1
IL611, IDD2
IL612, IDD1
IL612, IDD2
IL613, IDD1
IL613, IDD2
IL614, IDD1
IL614, IDD2
(4)
Logic High Output Voltage
VOH
VDD-0.1
VDD
Logic Low Output Voltage
VOL
Logic Output Current
Data Rate
Minimum Pulse Width
Propagation Delay Input to Output
(High to Low)
Propagation Delay Input to Output
(Low to High)
Average Propagation Delay Drift
Pulse Width Distortion |tPHL-tPLH| (2)
Propagation Delay Skew (3)
Output Rise Time (10-90%)
Output Fall Time (10-90%)
Common Mode Transient Immunity
Parameters
Data Rate
Typ.
55||9
0.16
2
4
2
2
6
2
4
1.3
2.6
1.3
1.3
Max.
67||10
0.165
2
0
3
0
6
3
3
0
9
3
6
0
2
0
4
2
2
0
6
2
4
4
1.3
2.6
VDD
VDD-0.5
0
0.1
0.5
0.8
IO
4
7
Switching Specifications CMOS Outputs
40
PW
25
tPHL
20
25
tPLH
20
25
50
PWD
7
10
tPSK
10
20
tR
2
4
tF
2
4
|CMH|,|CML|
15
20
Switching Specifications Open Drain Outputs
Symbol
Min.
Typ.
Max.
10
V
mA
Mbps
ns
ns
ns
ns
ns
ns
ns
kV/µs
Units
Mbps
ns
Test Conditions
TAMB = 25°C
VDD= 5 V, IIN=0
VDD= 3.3 V, IIN=0
IO = -20 µA
IO = -4 mA
IO = 20 µA
IO = 4 mA
50% Duty Cycle
50% Points, Vo
CL = 15 pF,
ICOIL = 10 mA
CL = 15 pF,
ICOIL = 10 mA
ps/°C
CL = 15 pF
CL = 15 pF
CL = 15 pF
CL = 15 pF
VT = 300 Vpeak
Test Conditions
50% Duty Cycle,
Rpullup = 1 kΩ
50% Duty Cycle,
Rpullup = 1 kΩ
Minimum Pulse Width
PW
Propagation Delay Input to Output
(High to Low)
Propagation Delay Input to Output
(Low to High)
Common Mode Transient Immunity
tPHL
20
25
ns
CL = 2 kΩ ||15 pF
tPLH
50
75
ns
CL = 2 kΩ ||15 pF
|CMH|,|CML|
100
Units
Ω||nH
Ω/°C
mA
mA
µA
mA
µA
mA
mA
mA
µA
mA
mA
mA
µA
mA
µA
mA
mA
mA
µA
mA
mA
mA
V
15
20
5
kV/µs
VT = 300 Vpeak
IL610 IL611 IL612
IL613 IL614
Notes:
1. Absolute Maximum ambient operating temperature means the device will not be damaged if operated under these conditions.
It does not guarantee performance.
2.
PWD is defined as |tPHL - tPLH|. %PWD is equal to the PWD divided by the pulse width.
3.
tPSK is equal to the magnitude of the worst case difference in tPHL and/or tPLH that will be seen between units at 25°C.
4.
The term VDD refers to the supply voltage on the output side of the isolated channel.
6
IL610 IL611 IL612
IL613 IL614
should be noted that we are concerned only with the
magnitude of the voltage across the coil. The absolute values
of Vin High and Vin Low are arbitrary.
Operation
The IL600 series are current mode devices. Changes in
current flow into the input coil result in logic state changes
at the output. One of the great advantages of the passive coil
input is that both single ended and differential inputs can be
handled without the need for reverse bias protection. The
internal GMR sensor switches the output to logic low if
current flows from (In-) to (In+). Only a single resistor is
required to limit the input coil to the recommended 10 mA.
This allows large input voltages to be used since there is no
semiconductor structure on the input.
The absolute maximum current through the coil of the IL600
series is 25 mA DC. However, it is important to limit input
current to levels well below this in all applications. The
worst case logic threshold current is 10 mA. While typical
threshold currents are substantially less than this, NVE
recommends designing a 10 mA logic threshold current in
each application. In all cases, the current must flow from Into In+ in the coil to switch the output low. This is true
regardless of true or inverted data configurations. Output
logic high is the zero input current state.
Figure 2. Series Resistor Calculation Equivalent Circuit.
Example 1. In this case, Tnom = 25ºC, Vin High is 24 V, Vin
Low is 1.8 V, and Icoil minimum is specified as 10 mA. Total
loop resistance is
(Vin High - Vin Low) 22.2
=
Ω = 2220 Ω
(R1 + Rcoil) =
Icoil
0.01
Therefore,
R1 = ( 2220 − 55) Ω = 2145 Ω
Figure 1 shows the response of the IL600 series. The GMR
bridge structure is designed such that the output of the
isolator is logic high when no field signal is present. The
output will switch to the low state with 10 mA of coil
current and the output will switch back to the high state
when the input current falls below 2 mA. This allows glitchfree interface with low slew rate signals.
Example 2. At a maximum operating temperature of 85°C,
Tmax = 85ºC, Tnom = 25ºC, Vin High = 5 V, Vin Low = 0 V,
and nominal Rcoil = 55 Ω. At Tmax = 85ºC
Rcoil = 55 + ( Tmax − Tmin ) × TCRcoil
= 55 + (85 - 25) × 0.165 = 55 + 9.9 = 65 Ω
Therefore, the recommended series resistor is
(VinHigh - VinLow)
- Rcoil
Icoil
5-0
=
− 65 = 435 Ω
0.01
R1 =
Allowance should also be made for the temperature
coefficient of the current limiting resistor to ensure that Icoil
is 10 mA at maximum operating temperature.
Power Supplies
Figure 1. IL600 Series Transfer Function
It is recommended that 47 nF ceramic capacitors be used to
decouple the power supplies. The capacitors must be placed
as close as possible to VDD for proper operation.
To calculate the value of the protection resistor (R1)
required, use Ohm’s law as shown in the examples below. It
7
IL610 IL611 IL612
IL613 IL614
Application Diagrams
CAN Bus
RS232
8
IL610 IL611 IL612
IL613 IL614
I2C
Single Phase Power Control
9
IL610 IL611 IL612
IL613 IL614
Inverting and Non-Inverting Circuits
Differential to Single Ended Conversion
10
IL610 IL611 IL612
IL613 IL614
Package drawings, dimensions and specifications
8-pin MSOP Package
8-pin SOIC Package
8-pin PDIP Package
11
IL610 IL611 IL612
IL613 IL614
0.15" 16-pin SOIC
0.30" 16-pin SOIC
12
IL610 IL611 IL612
IL613 IL614
Ordering information and valid part numbers.
13
IL610 IL611 IL612
IL613 IL614
About NVE
An ISO 9001 Certified Company
NVE Corporation is a high technology components manufacturer having the unique capability to combine leading edge Giant
Magnetoresistive (GMR) materials with integrated circuits to make high performance electronic components. Products include
Magnetic Field Sensors, Magnetic Field Gradient Sensors (Gradiometer), Digital Magnetic Field Sensors, Digital Signal Isolators
and Isolated Bus Transceivers.
NVE is a leader in GMR research and in 1994 introduced the world’s first products using GMR material, a line of GMR magnetic
field sensors that can be used for position, magnetic media, wheel speed and current sensing.
NVE is located in Eden Prairie, Minnesota, a suburb of Minneapolis. Please visit our Web site at www.nve.com or call 952-8299217 for information on products, sales or distribution.
NVE Corporation
11409 Valley View Road
Eden Prairie, MN 55344-3617 USA
Telephone: (952) 829-9217
Fax: (952) 829-9189
Internet: www.nve.com
e-mail: [email protected]
The information provided by NVE Corporation is believed to be accurate. However, no responsibility is assumed by NVE
Corporation for its use, nor for any infringement of patents, nor rights or licenses granted to third parties, which may result from
its use. No license is granted by implication, or otherwise, under any patent or patent rights of NVE Corporation. NVE
Corporation does not authorize, nor warrant, any NVE Corporation product for use in life support devices or systems or other
critical applications. The use of NVE Corporation’s products in such applications is understood to be entirely at the customer’s
own risk.
Specifications shown are subject to change without notice.
ISB-DS-001-IL600-A
January 28, 2005
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