AMI AMIS42700FHA

AMIS-42700 Dual High-Speed CAN Transceiver
Preliminary Data Sheet
1.0 Key Features
Controller area network (CAN) is a serial communication protocol, which supports distributed real-time control and multiplexing with
high safety level. Typical applications of CAN-based networks can be found in automotive and industrial environments.
The AMIS-42700 Dual-CAN transceiver is the interface between up to two physical bus lines and the protocol controller and will be
used for serial data interchange between different electronic units at more than one bus line. It can be used for both 12V and 24V
systems.
The circuit consists of following blocks:
• Two differential line transmitters
• Two differential line receivers
• Interface to the CAN protocol handler
• Interface to expand the number of CAN busses
• Logic block including repeater function and the feedback suppression
• Thermal shutdown circuit (TSD)
• Short to battery treatment circuit
Due to the wide common-mode voltage range of the receiver inputs, the AMIS-42700 is able to reach outstanding levels of
electromagnetic susceptibility (EMS). Similarly, extremely low electromagnetic emission (EME) is achieved by the excellent
matching of the output signals.
2.0 Key Features
• Fully compatible with the ISO 11898-2 standard
• Certified “Authentication on CAN Transceiver Conformance (d1.1)”
• High speed (up to 1 Mbit/s)
• Ideally suited for 12V and 24V industrial and automotive applications
• Low EME common-mode-choke is no longer required
• Differential receiver with wide common-mode range (+/- 35V) for high EMS
• No disturbance of the bus lines with an un-powered node
• Transmit data (TxD) dominant time-out function
• Thermal protection
• Bus pins protected against transients in an automotive environment
• Power down mode in which the transmitter is disabled
• Short circuit proof to supply voltage and ground
• Logic level inputs compatible with 3.3V devices
• ESD protection guaranteed up to ±8KV
3.0 Technical Characteristics
Table 1: Technical Characteristics
Symbol
Parameter
DC voltage at pin CANH
VCANH
DC voltage at pin CANL
VCANL
Differential bus output voltage in dominant state
Vi(dif)(bus_dom)
Propagation delay TxD to RxD
tpd(rec-dom)
Propagation delay TxD to RxD
t pd(dom-rec)
CM-range
Input common-mode range for comparator
VCM-peak
VCM-step
Common-mode peak
Common-mode step
Conditions
0 < VCC < 5.25V; no time limit
0 < VCC < 5.25V; no time limit
42.5Ω < RLT < 60Ω
See Figure 7
See Figure 7
Guaranteed differential receiver threshold and
leakage current
See Figure 8 and 9 (note)
See Figure 8 and 9 (note)
Notes: The parameters VCM-peak and VCM-step guarantee low EME.
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1
Min.
-45
-45
1.5
70
100
Max.
+45
+45
3
245
245
Unit
V
V
V
ns
ns
-35
+35
V
-500
-150
500
150
mV
mV
AMIS-42700 Dual High-Speed CAN Transceiver
Preliminary Data Sheet
4.0 Ordering Information
Marketing Name
Package
Temp. Range
AMIS 42700FHA
SOIC-20 300 G
-40°C…125°C
5.0 Block Diagram
VCC
12
Thermal
shutdown
2 x timer
clock
POR
VCC
14
Driver
control
Ri(cm)
Vcc/2
+
COMP
19
Timer
Feedbeck Surpression
CANL1
Timer
Feedbeck Surpression
CANH1
VCC
AMIS-40700
13
Logic
Unit
18
Driver
control
Ri(cm)
CANH2
CANL2
Vcc/2
+
COMP
Ri(cm)
Ri(cm)
PC20050502.1
8
VREF
10
3
ENB1 Text
4
Tx0
7
Rx0
2
9
Rint
ENB2
5
6
15
16
17
GND
Figure 1: Block Diagram
6.0 Typical Application
6.1 Application Description
AMIS-42700 is especially designed to provide the link between a CAN controller (protocol ic) and two physical busses. It is able to
operate in three different modes:
•
Dual CAN
•
A CAN bus extender
•
A CAN bus repeater
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AMIS-42700 Dual High-Speed CAN Transceiver
Preliminary Data Sheet
6.2 Application Schematics
VBAT
CAN BUS 1
5V-reg
CAN BUS 2
CD
100 nF
Vref
VCC
8 13 CANH1
EN1 10 12
EN2 2
Rx0 7
Tx0
14
AMIS-42700
4
Text
Rint
RLT
19
CANL1
60 Ω
CANH2
RLT
3
9
5
18
6 15 16 17
CANL2
60 Ω
GND
PC20050511.6
Figure 2: Application Diagram CAN-Bus Repeater
VBAT
CAN BUS 1
5V-reg
CD
CD
100 nF
100 nF
VCC
EN1 10
EN2 2
Rx0
µC
Vref
VCC
CAN
controller
Tx0
Text
Rint
7
4
8 13 CANH1
12
RLT
14
AMIS-42700
19
RLT
9
6 15 16 17
18
CANL2
GND
GND
Figure 3: Application Diagram Dual-CAN
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60 Ω
CANH2
3
5
PC20050502.3
CANL1
3
60 Ω
CAN BUS 2
AMIS-42700 Dual High-Speed CAN Transceiver
VBAT
Preliminary Data Sheet
CAN BUS 1
5V-reg
CD
CD
100 nF
100 nF
VCC
VCC
Vref
EN1 10 12
EN2 2
Rx0
µC
CAN
controller
Tx0
Text
Rint
7
4
8 13
CAN BUS 2
+5
CANH1
RLT
14
AMIS-42700
19
CANL1
60 Ω
CANH2
RLT
3
9
5
18
6 15 16 17
CANL2
60 Ω
GND
GND
+5
CAN BUS 3
CD
100 nF
VCC
EN1 10
EN2 2
Rx0
Tx0
Text
Rint
7
4
Vref
8 13 CANH1
12
RLT
14
AMIS-42700
19
CANL1
CANH2
RLT
3
9
5
6 15 16 17
PC20050502.9
18
CANL2
GND
Figure 4: Application Diagram CAN Bus Extender
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60 Ω
4
60 Ω
CAN BUS 4
AMIS-42700 Dual High-Speed CAN Transceiver
6.3 Pin Description
6.3.1 Pinout (top view)
1
20
NC
EN2
2
19
CANH2
Text
3
18
CANL2
Tx0
4
17
GND
GND
5
16
GND
GND
6
15
GND
Rx0
7
14
CANL1
Vref1
8
13
CANH1
Rint
9
12
VCC
EN1
10
11
NC
AMIS-42700
NC
PC20050502.2
Figure 4: Pin Configuration
6.3.2 Pin Description
Table 2: Pinout
Pin
Name
1
NC
2
ENB2
3
Text
4
Tx0
5
GND
6
GND
7
Rx0
8
VREF1
9
Rint
10
ENB1
11
NC
12
VCC
13
CANH1
14
CANL1
15
GND
16
GND
17
GND
18
CANL2
19
CANH2
20
NC
Description
Not connected
Enable input, bus system 2
Multi system transmitter input
Transmitter input
Ground connection, note 1
Ground connection, note 1
Receiver output
Reference voltage
Multi system receiver output
Enable input, bus system 1
Not connected
Positive supply voltage
CANH transceiver I/O bus system 1
CANL transceiver I/O bus system 1
Ground connection, note 1
Ground connection, note 1
Ground connection, note 1
CANL transceiver I/O bus system 2
CANH transceiver I/O bus system 2
Not connected
Notes:
1) In order to ensure the chip performance, these pins need to be connected to GND on the PCB.
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Preliminary Data Sheet
AMIS-42700 Dual High-Speed CAN Transceiver
Preliminary Data Sheet
7.0 Functional Description
7.1 Overall Functional Description
The CAN transceiver is specially designed to provide the link between the protocol IC (CAN controller) and two physical bus lines.
Data interchange between those two bus lines is realized via the interface. Bitwise arbitration is extended on both buses. A fault
like short circuit is limited to that bus line where it occurs. Data interchange from the protocol IC to the other bus system and on this
bus system itself can be continued.
The transceiver can also be used for only one bus system. If the connections for the second bus system are simply left open it
serves as a single transceiver for an electronic unit. For correct operation it is necessary to terminate an open bus. If not, the open
bus will disturb the other one, e.g. in case of open load.
The bus lines can have two logical states, dominant or recessive. A bus is in the recessive state when the driving sections of all
transceivers connected to the bus are passive. The differential voltage between the two wires is approximately zero. If at least one
driver is active the bus changes into the dominant state. This state is represented by a differential voltage greater than a minimum
threshold and therefore by a current flow through the terminating resistors of the bus line. The recessive state is overwritten by the
dominant state.
To provide an independent switch-off of the transceiver units for both bus systems by a third device (e.g. the µC) enables inputs for
the corresponding driving and receiving sections to be included.
7.2 Transmitter
The transceiver includes two transmitters, one for each bus line and a driver control circuit. Each transmitter is implemented as a
push and a pull driver. The drivers will be active if the transmission of a dominant bit is required. During the transmission of a
recessive bit all drivers are passive. The transmitters have a built-in current limiting circuit that protects the driver stages from
damage caused by accidental short circuit to either positive supply voltage or to ground. Additionally a thermal protection circuit is
integrated.
The driver control circuit ensures that the drivers are switched on and off with a controlled slope to limit EME. The driver control
circuit will be controlled itself by the thermal protection circuit, the timer circuit, the ENBx inputs, and the logic unit.
The dominant time out timer circuit prevents the output drivers from driving a permanent dominant state (blocking all network
communication) if pin Tx0 or the bus lines of the other bus are forced permanently dominant by a hardware and/or software failure
(see tdom(TxD)).
The enable signal ENBx allows the transmitter to be switched off by a third device (e.g. the µC). In the disabled state (ENBx =
high) the corresponding transmitter behaves as in the recessive state and does not depend on the input voltage at Tx0 nor on the
state of the other bus system.
7.3 Receiver
Two bus receiving sections sense the states of the bus lines. Each receiver section consists of an input filter and a fast and
accurate comparator. The aim of the input filter is to improve the immunity against high-frequency disturbances and also to
convert the voltage at the bus lines CANHx and CANLx, which can vary from –12V to +12V, to voltages in the range 0 to 5V, which
can be applied to the comparators.
The output signal of the comparators is gated by the ENBx signal. In the disabled state (ENBX = high) the output signal of the
comparator will be replaced by a permanently recessive state and does not depend on the bus voltage. In the enabled state the
receiver signal sent to the logic unit is identical to the comparator output signal.
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AMIS-42700 Dual High-Speed CAN Transceiver
Preliminary Data Sheet
7.4 Feedback Suppression
To provide proper function a feedback suppression must be included. This circuit replaces the reception of a dominant bit detected
by the receiving section with a recessive bit if the corresponding transmitter is active.
The feedback suppression must be activated immediately after the transmitter is requested to drive, i.e. before the receiver detects
the dominant state at the bus. After deactivating the transmitter, the feedback suppression must stay active long enough to
guarantee that the corresponding receiver has sufficient time to change its state from dominant to recessive.
Including the feedback, suppression is possible because a transmitter becomes active if the other bus system or Tx0 is in the
dominant state, so the reception of a dominant bit is already realized and need not be done additionally by this receiving section.
Without feedback suppression the whole system would stay constantly in the dominant state after the occurrence of one dominant
bit.
The logic is implemented in such a way that the suppression blocks in the two busses work independently of each other, and are
identical so that both busses have the same priority. Furthermore the oscillation or single pulsing, that could occur at the dominant
to recessive edge when the transceiver has received acknowledges from both busses, is avoided with this implementation.
If both buses are driven externally and go from dominant to recessive with some delay between each other, no spurious pulses are
seen at RINT and Rx0. However, it is possible to have the driving section of one bus going active while that bus is still driven
externally. To minimize the chance of this condition, an additional delay of typical 50ns is added that blocks the requirement to
drive the driving section after the bus is forced externally from dominant to recessive.
7.5 Logic Unit and CAN Controller Interface
The central logic unit provides data transfer from/to the digital interface to/from the two busses and from one bus to the other bus.
Digital input stages convert the input voltage at Tx0 and TEXT into a logical value for the logic unit. All digital inputs, including
ENBx, have an internal pull up resistor to ensure a recessive state when the input is not connected or is accidentally interrupted.
Output stages convert the logical value provided by the logic unit into voltages corresponding to the input signal specification of the
CAN controller at Rx0 and RINT. A dominant state on the bus line is represented by a low-level at the digital interface, a recessive
state is represented by a high-level.
Vref provides an analog voltage of Vcc/2 as a reference for CAN controller with analog inputs.
Input and output signals of the logic unit are related in such a way that a dominant state on any bus or Tx0 causes a dominant
state on both buses, RINT and Rx0.
The output signal at Rx0 corresponds to the inputs Tx0 and TEXT, independent of the state of the two enable inputs. This is
realized by an internal logical connection.
The pins TEXT and RINT are used for connecting the internal logics of several ICs to obtain versions with more than two bus
outputs. If a dominant bit is received from at least one of the two bus systems (under the condition of feedback suppression) or
from Tx0, RINT carries the low-level. Otherwise RINT is high. A low-level at TEXT activates both transmitters causing a dominant
state on both busses and sets Rx0 to the low-level. A high-level at TEXT does not influence the transceiver.
7.6 Power-on-Reset (POR)
While Vcc voltage is below the POR level, the POR circuit makes sure that:
• The counter is kept in the reset mode and stable state without current consumption
• Inputs are disabled (don't care)
• Outputs are high impedant; only Rx0 = high-level
• Analog blocks are in power down
• Oscillator not running and in power down
• CANHx and CANLx are recessive
• VREF output high impedant for POR not released
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AMIS-42700 Dual High-Speed CAN Transceiver
Preliminary Data Sheet
7.7 Time Out Timer
The Tx0 dominant time out timer circuit prevents the output drivers from driving a permanent dominant state (blocking all network
communication) if pin Tx0 or the bus lines of the other bus are forced permanently dominant by a hardware and/or software failure.
The timer is triggered by a negative edge of the TIMERIN signal. If the duration of the low-level on TIMERIN exceeds the internal
timer value TIMERDEL, the timer output TIMEROUT becomes high, disabling the transmitter (bus returns into the recessive state).
The timer is reset by a positive edge of the TIMERIN signal.
7.8 Over Temperature Detection
A thermal protection circuit is integrated to prevent the transceiver from damage if the junction temperature exceeds thermal
shutdown level. Because the transmitter dissipates most of the total power, the transmitter will be switched off only to reduce
power dissipation and IC temperature. All other IC functions continue to operate.
7.9 Fault Behavior
A fault like a short circuit is limited to that bus line where it occurs, hence data interchange from the protocol IC to the other bus
system is not affected.
When the voltage at the bus lines is going out of the normal operating range (-12V to +12V), the receiver is not allowed to
erroneously detect a dominant state.
7.10 Short Circuits
As specified in the maximum ratings, short circuits of the bus wires CANHx and CANLx to the positive supply voltage Vbat or to
ground must not destroy the transceiver. To provide sufficient safety for automotive applications the voltage range for permanent
short circuits is extended to 50V dc. A short circuit between CANHx and CANLx must not destroy the IC as well.
The dedicated comparator (L2VBAT) on CANL pin detects the short to battery and after debounce time-out switches off the
affected driver only.
The receiver of the affected driver has to operate normally.
7.11 Faulty Supply
In case of a faulty supply (missing connection of the electronic unit or the transceiver to ground, missing connection of the
electronic unit to Vbat or missing connection of the transceiver to Vcc) the power supply module of the electronic unit will operate
such that the transceiver is not supplied, i.e. the voltage Vcc is below the POR level. In this condition the bus connections of the
transceiver must be in the POR state.
If the ground line of the electronic unit is interrupted, Vbat may be applied to the Vcc pin (measured relative to the original ground
potential, to which the other units on the bus are connected).
7.12 Reverse Electronic Unit (ECU) Supply
If the connections for ground and supply voltage of an electronic unit (ECU) (max. 50V) which provides Vcc for the transceiver are
exchanged, this transceiver has a ground potential which may be up to 50V higher than that of the other transceivers. In this case
no transceiver must be destroyed even if several of them are connected via the bus system.
Any exchange among the six connections CANH1, CANH2, CANL1, CANL2, ground, and supply voltage of the electronic unit at
the connector of the unit must never lead to the destruction of any transceiver of the bus system.
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AMIS-42700 Dual High-Speed CAN Transceiver
Preliminary Data Sheet
8.0 Electrical Characteristics
8.1 Definitions
All voltages are referenced to GND. Positive currents flow into the IC. Sinking current means that the current is flowing into the
pin. Sourcing current means that the current is flowing out of the pin.
8.2 Absolute Maximum Ratings
Stresses above those listed in the following table may cause permanent device failure. Exposure to absolute maximum ratings for
extended periods may affect device reliability.
Table 3: Absolute Maximum Ratings
Symbol
Parameter
VCC
VCANH
VCANL
VTxD
VRxD
VS
VREF
Vtran(CANH)
Vtran(CANL)
Vtran(VSPLIT)
Supply voltage
Vesd(CANL/CANH)
ESD voltage at CANH and CANL pin
Vesd
ESD voltage at all other pins
Conditions
Min.
DC voltage at pin CANH
0 < VCC < 5.25V; no time limit
DC voltage at pin CANL
0 < VCC < 5.25V; no time limit
Max.
Unit
-0.3
+7
V
-45
+45
V
-45
+45
V
DC voltage at pin TxD
-0.3
VCC + 0.3
V
DC voltage at pin RxD
-0.3
VCC + 0.3
V
DC voltage at pin S
-0.3
VCC + 0.3
V
DC voltage at pin VREF
-0.3
VCC + 0.3
V
Transient voltage at pin CANH
Note 1
-150
+150
V
Transient voltage at pin CANL
Note 1
-150
+150
V
Transient voltage at pin Vsplit
Note 1
Note 2
Note 4
Note 2
Note 4
Note 3
-150
-8
-500
-2
-250
+150
+8
+500
+2
+250
100
V
kV
V
kV
V
mA
Latch-up
Static latch-up at all pins
Tstg
Tamb
Tjunc
Storage temperature
-55
+155
°C
Ambient temperature
-40
+125
°C
Maximum junction temperature
-40
+150
°C
Notes:
1) Applied transient waveforms in accordance with “ISO 7637 part 3”, test pulses 1, 2, 3a, and 3b (see Figure 4).
2) Standardized human body model (HBM) ESD pulses in accordance to MIL883 method 3015. Supply pin 8 is ±2 kV.
3) Static latch-up immunity: static latch-up protection level when tested according to EIA/JESD78.
4) Standardized charged device model ESD pulses when tested according to EOS/ESD DS5.3-1993.
8.3 Thermal Characteristics
Symbol
Parameter
Conditions
Value
Unit
Rth(vj-a)
Rth(vj-s)
Thermal resistance from junction to ambient in SO8 package
In free air
145
K/W
Thermal resistance from junction to substrate of bare die
In free air
45
K/W
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AMIS-42700 Dual High-Speed CAN Transceiver
Preliminary Data Sheet
8.4 DC Characteristics
VCC = 4.75 to 5.25V; V33 = 2.9 to 3.6V; Tjunc = -40 to +150°C; RLT =60Ω unless specified otherwise.
Table 4: DC Characteristics
Symbol
Parameter
Supply (pin VCC)
ICC
Supply current
Transmitter Data Input (pin TxD)
High-level input voltage
VIH
Low-level input voltage
VIL
High-level input current
IIH
Low-level input current
IIL
Input capacitance
Ci
Mode Select (pin S)
High-level input voltage
VIH
Low-level input voltage
VIL
High-level input current
IIH
Low-level input current
IIL
Receiver Data Output (pin RxD)
High-level output voltage
VOH
Low-level output voltage
VOL
High-level output current
Ioh
Low-level output current
Iol
Reference Voltage Output (pin VREF)
Reference output voltage
VREF
Reference output voltage for full common
VREF_CM
mode range
Bus Lines (pins CANH and CANL)
Recessive bus voltage at pin CANH
Vo(reces)(CANH)
Recessive bus voltage at pin CANL
Vo(reces)(CANL)
Io(reces) (CANH)
Recessive output current at pin CANH
Io(reces) (CANL)
Recessive output current at pin CANL
Vo(dom) (CANH)
Vo(dom) (CANL)
Dominant output voltage at pin CANH
Dominant output voltage at pin CANL
Vi(dif) (bus)
Differential bus input voltage (VCANH - VCANL)
Io(sc) (CANH)
Io(sc) (CANL)
Vi(dif)(th)
Short circuit output current at pin CANH
Short circuit output current at pin CANL
Differential receiver threshold voltage
Vihcm(dif) (th)
Differential receiver threshold voltage for high
common-mode
Vi(dif) (hys)
Differential receiver input voltage hysteresis
Ri(cm)(CANH)
Ri(cm) (CANL)
Common-mode input resistance at pin CANH
Common-mode input resistance at pin CANL
Matching between pin CANH and pin CANL
common-mode input resistance
Differential input resistance
Input capacitance at pin CANH
Input capacitance at pin CANL
Differential input capacitance
Input leakage current at pin CANH
Ri(cm)(m)
Ri(dif)
Ci(CANH)
Ci(CANL)
Ci(dif)
ILI(CANH)
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Conditions
Min.
Dominant; VTXD =0V
Recessive; VTXD =VCC
Typ.
Max.
Unit
45
4
65
8
mA
mA
Output recessive
Output dominant
VTxD =VCC
VTxD =0V
Not tested
2.0
-0.3
-1
-75
-
0
-200
5
VCC
+0.8
+1
-350
10
V
V
µA
µA
pF
Silent mode
High-speed mode
VS =2V
VSTB =0.8V
2.0
-0.3
20
15
30
30
VCC
+0.8
50
45
V
V
µA
µA
IRXD = - 10mA
IRXD = 6mA
Vo=0.7 x VCC
Vo=0.3 x VCC
0.6 x VCC
-5
5
0.75 x VCC
0.25
-10
10
0.45
-15
15
V
V
mA
mA
-50µA < IVREF < +50µA
-35V <VCANH< +35V;
-35V <VCANL< +35V
0.45 x VCC
0.50 x VCC
0.55 x VCC
V
0.40 x VCC
0.50 x VCC
0.60 x VCC
V
2.0
2.0
2.5
2.5
3.0
3.0
V
V
-2.5
-
+2.5
mA
-2.5
-
+2.5
mA
3.0
0. 5
3.6
1.4
4.25
1.75
V
V
1.5
2.25
3.0
V
-120
0
+50
mV
-45
45
-70
70
-95
120
mA
mA
0.5
0.7
0.9
V
0.3
0.7
1.05
V
50
70
100
mV
15
15
26
26
37
37
KΩ
KΩ
-3
0
+3
%
25
50
7.5
7.5
3.75
170
75
20
20
10
250
KΩ
pF
pF
pF
µA
VTxD =VCC; no load
VTxD =VCC; no load
-35V <VCANH< +35V;
0V <VCC < 5.25V
-35V <VCANL < +35V;
0V <VCC < 5.25V
VTxD = 0V
VTxD = 0V
VTxD = 0V; dominant;
42.5Ω < RLT < 60Ω
VTxD =VCC; recessive;
no load
VCANH =0V;VTxD =0V
VCANL =36V; VTxD =0V
-5V <VCANL < +12V;
-5V <VCANH < +12V;
see Figure 5
-35V <VCANL < +35V;
-35V <VCANH < +35V;
see Figure 5
-35V <VCANL < +35V;
-35V <VCANH < +35V;
see Figure 5
VCANH =VCANL
VTxD =VCC; not tested
VTxD =VCC; not tested
VTxD =VCC; not tested
VCC =0V; VCANH = 5V
10
10
AMIS-42700 Dual High-Speed CAN Transceiver
Table 4: DC Characteristics (Continued)
Symbol
Parameter
Bus Lines (pins CANH and CANL)
Input leakage current at pin CANL
ILI(CANL)
Common-mode peak during transition from
VCM-peak
dom → rec or rec → dom
Difference in common-mode between dominant
VCM-step
and recessive state
Power-on-Reset
PORL
Conditions
VCC =0V; VCANL = 5V
Thermal Shutdown
Shutdown junction temperature
Tj(sd)
Timing Characteristics (see Figure 6 and 7)
Delay TxD to bus active
td(TxD-BUSon)
Delay TxD to bus inactive
td(TxD-BUSoff)
Delay bus active to RxD
td(BUSon-RXD)
Delay bus inactive to RxD
td(BUSoff-RXD)
Propagation delay TxD to RxD from recessive
tpd(rec-dom)
to dominant
Propagation delay TxD to RxD from dominant
td(dom-rec)
to recessive
TXD dominant time for time out
tdom(TXD)
Min.
Typ.
Max.
Unit
10
170
250
µA
See Figure 8 and 9
-500
500
mV
See Figure 8 and 9
-150
150
mV
CANH, CANL, Vref in tristate below POR level
POR level
Preliminary Data Sheet
2.2
3.5
4.7
V
140
160
190
°C
Vs = 0V
Vs = 0V
Vs = 0V
Vs = 0V
40
30
25
65
85
60
55
100
130
105
105
155
ns
ns
ns
ns
Vs = 0V
70
230
ns
Vs = 0V
100
245
ns
VTxD = 0V
250
750
µs
8.5 Measurement Setups and Definitions
Schematics are given for single CAN transceiver.
+5V
100 nF
VCC
Vref
8 13 CANH1
12
Text
Rint
1 nF
Transient
Generator
3
14
9
AMIS-42700
Tx0
19
CANL1
CANH2
1 nF
4
Rx0
7
10
2
17 16 15
18
5
6
CANL2
GND
EN1
PC20050502.5
EN2
Figure 4: Test Circuit for Automotive Transients
VRxD
High
Low
Hysteresis
PC20040829.7
0,9
0,5
Figure 5: Hysteresis of the Receiver
AMI Semiconductor – Rev. 1.4, May 05 - Preliminary
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11
Vi(dif)(hys)
450
AMIS-42700 Dual High-Speed CAN Transceiver
Preliminary Data Sheet
+5V
100 nF
Vref
VCC
8 13 CANH1
12
Text
3
14
Rint
9
AMIS-42700
Tx0
19
CANL1
7
10
2
17 16 15
6
5
18
CANL2
GND
EN1
CLT
60 Ω
100 pF
CANH2
4
Rx0
RLT
RLT
CLT
60 Ω
100 pF
PC20050502.4
EN2
Figure 6: Test Circuit for Timing Characteristics
HIGH
LOW
Tx0
CANHx
CANLx
dominant
Vi(dif) =
VCANH - VCANL
0,9V
0,5V
recessive
Rx0
0,7 x VCC
0,3 x VCC
td(TxD-BUSon)
td(TxD-BUSoff)
td(BUSon-RxD)
tpd(rec-dom)
tpd(dom-rec)
td(BUSoff-RxD)
Figure 7: Timing Diagram for AC Characteristics
AMI Semiconductor – Rev. 1.4, May 05 - Preliminary
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12
PC20050502.7
AMIS-42700 Dual High-Speed CAN Transceiver
Preliminary Data Sheet
+5V
100 nF
VCC
Vref
Text
Rint
Active Probe
14
9
AMIS-42700
19
CANL1
7
10
2
17 16 15
6
18
5
Spectrum Anayzer
6.2 kΩ
CANH2
30 Ω
4
Rx0
10 nF
3
Tx0
Gen
6.2 kΩ
8 13 CANH1
12
30 Ω
CANL2
47 nF
GND
EN1
EN2
PC20050502.6
Figure 8: Basic Test Setup for Electromagnetic Measurement
CANHx
CANLx
recessive
Vi(com) =
VCANHx + VCANLx
VCM-step
VCM-peak
PC20050502.8
VCM-peak
Figure 9: Common-mode Voltage Peaks (see measurement setup Figure 8)
AMI Semiconductor – Rev. 1.4, May 05 - Preliminary
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13
AMIS-42700 Dual High-Speed CAN Transceiver
Preliminary Data Sheet
9.0 Package Outline
SOIC-20: Plastic small outline; 20 leads; body width 300mil.
AMI Semiconductor – Rev. 1.4, May 05 - Preliminary
www.amis.com
AMIS reference: SOIC300 20 300 G
14
AMIS-42700 Dual High-Speed CAN Transceiver
Preliminary Data Sheet
10.0 Soldering
10.1 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.
10.2 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
re-flowing; 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.
10.3 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.
10.4 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 11: Soldering Process
Package
Soldering Method
Wave
Re-flow(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.
AMI Semiconductor – Rev. 1.4, May 05 - Preliminary
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15
AMIS-42700 Dual High-Speed CAN Transceiver
Preliminary Data Sheet
11.0 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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16