AMI AMIS

AMIS-30600 LIN Transceiver
Data Sheet
1.0 Key Features
LIN-Bus Transceiver
•
LIN compliant to specification rev. 1.3 and rev. 2.0
•
I2T high voltage technology
•
Bus voltage ± 40V
•
Transmission rate up to 20 kBaud
•
SOIC-150-8 Package
Protection
•
Thermal shutdown
•
Indefinite short circuit protection to supply and ground
•
Load dump protection (45V)
Power Saving
•
Operating voltage = 4.75 to 5.25V
•
Power down supply current < 50µA
EMS Compatibility
•
Integrated filter and hysteresis for receiver
EMI Compatibility
•
Integrated slope control for transmitter
•
Slope control dependant from Vbat to enable maximum capacitive-load
2.0 General Description
The single-wire transceiver AMIS-30600 is a monolithic integrated circuit in a SOIC-8 package. It works as an interface between
the protocol controller and the physical bus.
The AMIS-30600 is especially suitable to drive the bus line in LIN systems in automotive and industrial applications. Further it can
be used in standard ISO9141 systems.
In order to reduce the current consumption the AMIS-30600 offers a stand-by mode. A wake-up caused by a message on the bus
pulls the INH-output high until the device is switched to normal operation mode.
The transceiver is implemented in I2T100 technology enabling both high-voltage analog circuitry and digital functionality to co-exist
on the same chip.
The AMIS-30600 provides an ultra-safe solution to today’s automotive in-vehicle networking (IVN) requirements by providing
unlimited short circuit protection in the event of a fault condition.
3.0 Ordering Information
Table 1: Ordering Code
Marketing Name
Package
Temp. Range
AMIS30600AGA
SOIC 150 8 150 4
-40°C…125°C
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AMIS-30600 LIN Transceiver
Data Sheet
4.0 Block Diagram
8
VBB
3
7
State
&
Wake-up
Control
INH
Thermal
shutdown
10 kΩ
30 kΩ
2
EN
VCC
1
RxD
COMP
VCC
40 kΩ
4
TxD
6
LIN
Filter
AMIS-30600
Slope
Control
5
GND
PC20050113.3
Figure 1: Block Diagram
5.0 Typical Application
5.1 Application Schematic
Master Node
IN
VBAT
5V-reg
10 µF
8
1 kΩ
7
1 nF
GND
7
4
2
5
8
1
LIN
controller
LIN
6
AMIS30600
EN
4
2
2
GND
GND
GND
VCC
VCC
3
RxD
TxD
OUT
100 nF
3
AMIS30600
5V-reg
VBB INH
VCC
VCC
1
6
IN
10 µF
100 nF
VBB INH
LIN
Slave Node
VBAT
OUT
5
RxD
TxD
LIN
controller
EN
2
GND
GND
KL30
LIN-BUS
PC20050113.5
KL31
Figure 2: Application Diagram
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AMIS-30600 LIN Transceiver
Data Sheet
5.2 Pin Description
5.2.1 Pin Out (top view)
1
EN
2
VCC
3
TxD
4
AMIS30600
RxD
8
INH
7
VBB
6
LIN
5
GND
PC20041204.3
Figure 3: Pin Configuration
5.2.2 Pin Description
Table 2: Pinout
Pin Name Description
1
RxD
Receive data output; low in dominant state
2
EN
Enable input; transceiver in normal operation mode when high
3
VCC
5V supply input
4
TxD
Transmit data input; low in dominant state; internal 40 KΩ pull-up
5
GND
Ground
6
LIN
LIN bus output/input; low in dominant state; internal 30 KΩ pull-up
7
VBB
Battery supply input
8
INH
Inhibit output; to control a voltage regulator; becomes high when wake-up via LIN bus occurs
5.3 Application Information
Start Up
Power Up
Normal Mode
EN
INH
Vcc
High
High
On
Power-up
EN Æ High
Stand-By Mode
EN Æ Low
EN Æ High
(Vcc Æ On)
Sleep Mode
EN
Low
INH
Vcc
Floating
Off
Figure 4: State Diagram
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EN
INH
Vcc
Low
High
On
Wake-up
t > twake
PC20050113.1
AMIS-30600 LIN Transceiver
Data Sheet
For fail safe reasons the AMIS-30600 already has an internal pull up resistor of 30kΩ implemented. To achieve the required
timings for the dominant to recessive transition of the bus signal an additional external termination resistor of 1kΩ is required. It is
recommended to place this resistor in the master node. To avoid reverse currents from the bus line into the battery supply line in
case of an unpowered node, it is recommended to place a diode in series to the external pull up. For small systems (low bus
capacitance) the EMC performance of the system is supported by an additional capacitor of at least 1nF in the master node (see
Figure 2, Typical Application Diagram).
The AMIS-30600 has a slope which depends of the supply Vbat. This implementation guarantees biggest slope-time under all load
conditions. The rising slope has to be slower then the external RC-time-constant, otherwise the slope will be terminated by the RCtime-constant and no longer by the internal slope-control. This would effect the symmetry of the bus-signal and would limit the
maximum allowed bus-speed.
A capacitor of 10µF at the supply voltage input VB buffers the input voltage. In combination with the required reverse polarity diode
this prevents the device from detecting power down conditions in case of negative transients on the supply line.
In order to reduce the current consumption, the AMIS-30600 offers a sleep operation mode. This mode is selected by switching the
enable input EN low (see Figure 4, State Diagram).
In the sleep mode a voltage regulator can be controlled via the INH output in order to minimize the current consumption of the
whole application. A wake-up caused by a message on the communication bus automatically enables the voltage regulator by
switching the INH output high. In case the voltage regulator control input is not connected to INH output or the micro-controller is
active respectively, the AMIS-30600 can be set in normal operation mode without a wake-up via the communication bus.
6.0 Electrical Characteristics
6.1 Absolute Maximum Ratings
Maximum ratings are absolute ratings; exceeding any one of these values may cause irreversible damage to the integrated circuit.
Table 4: Absolute Maximum Ratings
Symbol
Parameter
Conditions
Min.
Max.
Unit
VCC
Supply voltage
-0.3
+7
V
VBB
Battery supply voltage
-0.3
+40
V
VLIN
DC voltage at pin LIN
0 < VCC < 5.50V; note 1
-40
+40
V
VINH
DC voltage at pin INH
0 < VCC < 5.50V
-0.3
VBB + 0.3
V
VTxD
DC voltage at pin TxD
0 < VCC < 5.50V
-0.3
VCC + 0.3
V
VRxD
DC voltage at pin RxD
0 < VCC < 5.50V
-0.3
VCC + 0.3
V
VEN
DC voltage at pin EN
0 < VCC < 5.50V
-0.3
VCC + 0.3
V
Vesd(LIN)
Electrostatic discharge voltage at LIN pin
Note 2
-4
+4
kV
Vesd
Electrostatic discharge voltage at all other pins
Note 2
-4
+4
kV
Vtran(LIN)
Transient voltage at pin LIN
Note 3
-150
+150
V
Vtran(VBB)
Transient voltage at pin VBB
Note 4
-150
+150
V
Tamb
Ambient temperature
-40
+150
°C
Notes:
1.
2.
3.
4.
80V version available, contact sales for details.
Standardized human body model system ESD pulses in accordance to IEC 1000.4.2.
Applied transient waveforms in accordance with “ISO 7637 parts 1 & 3” capacitive coupled test pulses 1 (-100V),
2 (+100V), 3a (-150V), and 3b (+150V). See Figure 8.
Applied transient waveforms in accordance with “ISO 7637 parts 1 & 3” direct coupled test pulses 1 (-100V), 2 (+75V),
3a (-150V), 3b (+150V), and 5 (+80V). See Figure 8.
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AMIS-30600 LIN Transceiver
Data Sheet
6.2 Operating Range
Table 5: Operating Range
Symbol
Parameter
Max.
Unit
VCC
Supply voltage
Min.
4.75
Typ.
+5.25
V
VBB
Battery supply voltage
7.3
+18
V
Tjunc
Maximum junction temperature
-40
+150
°C
Tjsd
Thermal shutdown temperature
+150
Rthj-a
Thermal resistance junction to ambient
+170
+190
185
°C
°C/W
6.3 DC Electrical Characteristics
VCC = 4.75 to 5.25V; VBB = 7.3 to 18V; VEN > VEN,on ; Tamb = -40 to +125°C; RL = 500Ω unless specified otherwise. All voltages with
respect to ground; positive current flowing into pin; unless otherwise specified.
Table 6: DC Characteristics
Symbol
Parameter
Conditions
Min.
Typ.
Max.
Unit
400
250
1
100
35
700
500
1.5
200
55
µA
µA
mA
µA
µA
0.25
1
µA
0.7 x VCC
-
VCC
V
0
-
Supply (pin VCC and pin VBB)
ICC
5V supply current
IBB
Battery supply current
IBB
Battery supply current
Dominant; VTxD =0V
Recessive; VTxD =VCC
Dominant; VTxD =0V
Recessive; VTxD =VCC
Sleep mode; VINH = 0V
ICC
5V supply current
Sleep mode; VINH = 0V
Transmitter Data Input (pin TxD)
VIH
High-level input voltage
Output recessive
VIL
Low-level input voltage
Output dominant
RTxD,pu
Pull-up resistor to Vcc
0.3 x VCC
V
24
60
kΩ
0.8 x VCC
VCC
V
0
0.2 x VCC
V
Receiver Data Output (pin RxD)
VOH
High-level output voltage
IRXD = -10mA
VOL
Low-level output voltage
IRXD = 5mA
Enable Input (pin EN)
VEN,on
High-level input voltage
Normal mode
VEN,off
Low-level input voltage
Low power mode
REN,pd
Pull-down resistor to GND
0.7 x VCC
-
VCC
V
0
-
0.3 x VCC
V
6
10
15
kΩ
Inhibit Output (pin INH)
VINH,d
High-level voltage drop: VINH,d = VBB - VINH
IINH = - 0.15mA
0.5
1.0
V
IINH,lk
Leakage current
Sleep mode; VINH = 0V
-5.0
-
5.0
µA
VTxD =VCC
VTxD = 0V
VTxD = 0V; Ibus = 40mA
Vbus,short = 18V
VCC=VBB=0V; Vbus=8V
VCC=VBB=0V; Vbus=20V
VTxD = 0V
0.9 x VBB
-
0
-
40
-400
VBB
0.15 x VBB
1.4
130
V
V
V
mA
Bus Line (pin LIN)
Vbus,rec
Recessive bus voltage at pin LIN
Vbus,dom
Dominant output voltage at pin LIN
Ibus,sc
Bus short circuit current
Ibus,lk
Bus leakage current
Rbus
Bus pull-up resistance
Vbus,rd
Receiver threshold: recessive to dominant
Vbus,dr
Receiver threshold: dominant to recessive
Vq
Receiver hysteresis
VWAKE
Wake-up threshold voltage
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Vbus,hys=Vbus,rec-Vbus,dom
20
85
-200
5
30
0.4 x VBB
0.48 x VBB
0.4 x VBB
0.52 x VBB
0.6 x VBB
V
0.05 x VBB
0.04 x VBB
0.175 x VBB
V
0.6 x VBB
V
0.4 x VBB
5
µA
20
47
kΩ
0.6 x VBB
V
AMIS-30600 LIN Transceiver
Data Sheet
6.4 AC Electrical Characteristics
VCC = 4.75 to 5.25V; VBB = 7.3 to 18V; VEN > VEN,on ; Tamb = -40 to +125°C; RL = 500Ω unless specified otherwise.
Load for slope definitions (typical loads) = [L1] 1nF 1kΩ / [L2] 6.8nF 600Ω / [L3] 10nF 500Ω.
Table 7: AC Characteristics According to LIN V1.3
Symbol
Parameter
Conditions
Min.
Typ.
Max.
Unit
Dynamic Transceiver Characteristics According to LIN v1.3
t _slope_F
Slope time falling edge
See Figure 6
4
-
24
µs
t _slope_R
Slope time rising edge
See Figure 6
4
-
24
µs
t _slope _Sym
Slope time symmetry
Propagation delay Bus dominant
to RxD = low; note 1
Propagation delay Bus recessive
to RxD = high; note 1
Wake-up delay time
t _slope_F - t _slope_R
-8
-
+8
µs
See Figure 5, 6
2
6
µs
See Figure 5, 6
2
6
µs
100
200
µs
T_rec_F
T_rec_R
tWAKE
Notes:
1.
30
Not measured on ATE.
VCC = 4.75 to 5.25V; VBB = 7.3 to 18V; VEN > VEN,on ; Tamb = -40 to +125°C; RL = 500Ω unless specified otherwise.
Load for slope definitions (typical loads) = [L1] 1nF 1kΩ / [L2] 6.8nF 600Ω / [L3] 10nF 500Ω.
Table 8: AC Characteristics According to LIN V2.0
Symbol
Parameter
Dynamic Receiver Characteristics according to LIN v2.0
Propagation delay bus dominant
trx_pdr
to RxD = low; note 1
Propagation delay Bus recessive
trx_pdf
to RxD = high; note 1
trx_sym
Symmetry of receiver propagation delay
Conditions
Max.
Unit
See Figure 7
6
µs
See Figure 7
6
µs
+2
µs
trx_pdr - trx_pdf
Min.
-2
Typ.
-
Dynamic Transmitter Characteristics according to LIN v2.0
D1
Duty cycle 1 = tBus_rec(min)/(2 x tBit);
See Figure 7
D1
Duty cycle 1 = tBus_rec(min)/(2 x tBit);
See Figure 7
D2
Duty cycle 2 = tBus_rec(max)/(2 x tBit);
See Figure 7
Notes:
1.
THRec(max)= 0.744 x Vbat;
THDom(max)= 0.581 x Vbat;
Vbat = 7.0V ... 18V; tBit= 50µs
THRec(max)= 0.744 x Vbat;
THDom(max)= 0.581 x Vbat;
Vbat = 7.0V; tBit= 50µs;
tamb = -40°C
THRec(min)= 0.284 x Vbat;
THDom(min)= 0.422 x Vbat;
Vbat = 7.6V ... 18V; tBit= 50µs;
Not measured on ATE.
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0.396
0.5
0.366
0.5
0.5
0.581
AMIS-30600 LIN Transceiver
Data Sheet
Vbat
VBB
100 nF
7
+5 V
RL
3
100 nF
AMIS30600
4
TxD
6
3 INH
RxD 1
CL
5
2
20 pF
LIN
Load
RL
CL
L1
1 kΩ
1 nF
L2
600 Ω 6.8 nF
L3
500 Ω 10 nF
GND
EN
PC20041207.1
Figure 5: Test Circuit for Timing Characteristics
LIN
50%
t
RxD
T_rec_F
T_rec_R
50%
50%
t
LIN
PC20041206.1
60%
60%
PC20041204.1
40%
40%
t
T_slope_F
T_slope_R
PC20041206.2
Figure 6: Timing Diagram for AC Characteristics According to LIN 1.3
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AMIS-30600 LIN Transceiver
TxD
Data Sheet
tBIT
tBIT
50%
t
tBUS_dom(max)
LIN
tBUS_rec(min)
THRec(max)
THDom(max)
Thresholds
receiver 1
THRec(min)
THDom(min)
Thresholds
receiver 2
t
tBUS_dom(min)
RxD
tBUS_rec(max)
( receiver 2)
50%
trx_pdr
trx_pdf
t
PC20041206.3
Figure 7: Timing Diagram for AC Characteristics According to LIN 2.0
+13.5 V
VBB
100 nF
VCC
+5.25 V
7
3
1 kΩ
100 nF
TxD
4
EN
AMIS30600
6
LIN
1 nF
1 nF
3
2
1
INH
5
GND
RxD
20 pF
PC20050113.2
Figure 8: Test Circuit for Transient Measurements
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Transient
Generator
AMIS-30600 LIN Transceiver
Data Sheet
7.0 Package Outline
SOIC-8: Plastic small outline; 8 leads; body width 150 mil; JEDEC: MS-012. AMIS reference: SOIC150 8 150 G
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AMIS-30600 LIN Transceiver
Data Sheet
8.0 Soldering
8.1 Introduction to Soldering Surface Mount Packages
This text gives a very brief insight to a complex technology. A more in-depth account of soldering ICs can be found in the AMIS
“Data Handbook IC26; Integrated Circuit Packages” (document order number 9398 652 90011).
There is no soldering method that is ideal for all surface mount IC packages. Wave soldering is not always suitable for surface
mount ICs, or for printed-circuit boards with high population densities. In these situations reflow soldering is often used.
8.2 Re-flow Soldering
Re-flow soldering requires solder paste (a suspension of fine solder particles, flux and binding agent) to be applied to the printedcircuit board by screen printing, stencilling or pressure-syringe dispensing before package placement. Several methods exist for
reflowing; for example, infrared/convection heating in a conveyor type oven.
Throughput times (preheating, soldering and cooling) vary between 100 and 200 seconds depending on heating method.
Typical re-flow peak temperatures range from 215 to 250°C. The top-surface temperature of the packages should preferably be
kept below 230°C.
8.3 Wave Soldering
Conventional single wave soldering is not recommended for surface mount devices (SMDs) or printed-circuit boards with a high
component density, as solder bridging and non-wetting can present major problems. To overcome these problems the doublewave soldering method was specifically developed.
If wave soldering is used the following conditions must be observed for optimal results:
• Use a double-wave soldering method comprising a turbulent wave with high upward pressure followed by a smooth
laminar wave.
• For packages with leads on two sides and a pitch (e):
o Larger than or equal to 1.27mm, the footprint longitudinal axis is preferred to be parallel to the transport direction
of the printed-circuit board;
o Smaller than 1.27mm, the footprint longitudinal axis must be parallel to the transport direction of the printedcircuit board. The footprint must incorporate solder thieves at the downstream end.
• For packages with leads on four sides, the footprint must be placed at a 45º angle to the transport direction of the printedcircuit board. The footprint must incorporate solder thieves downstream and at the side corners.
During placement and before soldering, the package must be fixed with a droplet of adhesive. The adhesive can be applied by
screen printing, pin transfer or syringe dispensing. The package can be soldered after the adhesive is cured.
Typical dwell time is four seconds at 250°C. A mildly-activated flux will eliminate the need for removal of corrosive residues in most
applications.
8.4 Manual Soldering
Fix the component by first soldering two diagonally-opposite end leads. Use a low voltage (24V or less) soldering iron applied to
the flat part of the lead. Contact time must be limited to 10 seconds at up to 300°C.
When using a dedicated tool, all other leads can be soldered in one operation within two to five seconds between 270 and 320°C.
Table 9: Soldering Process
Package
Soldering Method
Wave
Reflow(1)
BGA, SQFP
Not suitable
Suitable
HLQFP, HSQFP, HSOP, HTSSOP, SMS
Not suitable (2)
Suitable
PLCC (3) , SO, SOJ
Suitable
Suitable
LQFP, QFP, TQFP
Not recommended (3)(4)
Suitable
SSOP, TSSOP, VSO
Not recommended (5)
Suitable
Notes:
1.
All surface mount (SMD) packages are moisture sensitive. Depending upon the moisture content, the maximum temperature (with respect to time) and body size
of the package, there is a risk that internal or external package cracks may occur due to vaporization of the moisture in them (the so called popcorn effect). For
details, refer to the drypack information in the “Data Handbook IC26; Integrated Circuit Packages; Section: Packing Methods.”
2.
These packages are not suitable for wave soldering as a solder joint between the printed-circuit board and heatsink (at bottom version) can not be achieved, and
as solder may stick to the heatsink (on top version).
3.
If wave soldering is considered, then the package must be placed at a 45° angle to the solder wave direction. The package footprint must incorporate solder
thieves downstream and at the side corners.
4.
Wave soldering is only suitable for LQFP, TQFP and QFP packages with a pitch (e) equal to or larger than 0.8mm; it is definitely not suitable for packages with a
pitch (e) equal to or smaller than 0.65mm.
5.
Wave soldering is only suitable for SSOP and TSSOP packages with a pitch (e) equal to or larger than 0.65mm; it is definitely not suitable for packages with a
pitch (e) equal to or smaller than 0.5mm.
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AMIS-30600 LIN Transceiver
Data Sheet
9.0 Company or Product Inquiries
For more information about AMI Semiconductor, our technology and our product, visit our website at: http://www.amis.com
North America
Tel: +1.208.233.4690
Fax: +1.208.234.6795
Europe
Tel: +32 (0) 55.33.22.11
Fax: +32 (0) 55.31.81.12
Devices sold by AMIS are covered by the warranty and patent indemnification provisions appearing in its Terms of Sale only. AMIS makes no warranty, express,
statutory, implied or by description, regarding the information set forth herein or regarding the freedom of the described devices from patent infringement. AMIS
makes no warranty of merchantability or fitness for any purposes. AMIS reserves the right to discontinue production and change specifications and prices at any
time and without notice. AMI Semiconductor's products are intended for use in commercial applications. Applications requiring extended temperature range,
unusual environmental requirements, or high reliability applications, such as military, medical life-support or life-sustaining equipment, are specifically not
recommended without additional processing by AMIS for such applications. Copyright ©2005 AMI Semiconductor, Inc.
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