MAX13041 Datasheet, PDF(15/21 Page) Maxim Integrated Products – ±80V Fault-Protected High-Speed CAN Transceiver with Low-Power Management and Wake-On CAN

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MAX13041 Datasheet, PDF (15/21 Pages) Maxim Integrated Products – ±80V Fault-Protected High-Speed CAN Transceiver with Low-Power Management and Wake-On CAN

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Â±80V Fault-Protected High-Speed CAN Transceiver

with Low-Power Management and Wake-On CAN

normal mode, prior to the fourth dominant-to-recessive

transition on TXD. A low level on ERR indicates a local

wake-up has occurred.

Bus Failure Flag

The bus failure flag is set when the MAX13041 detects

a CAN bus short-circuit to VBAT, VCC, or GND for four

consecutive dominant-recessive cycles on TXD. The

flag is cleared when the MAX13041 leaves normal

mode. The bus failure flag is externally indicated as a

logic low on ERR in normal mode, after the fourth domi-

nant-to-recessive transition on TXD.

Local Failure Flag

The local failure flag indicates five separate local failure

conditions (see Fault Protection & Fail-Safes section).

When one or more local failure conditions have

occurred, the local failure flag is set. The flag is cleared

when the MAX13041 enters normal mode or when RXD

goes logic-low while TXD is logic-high. The local failure

flag is externally indicated as a logic-low on ERR when

the MAX13041 is placed into PWON/listen-only mode

from normal mode.

Wake-On CAN

The MAX13041 provides wake-on-CAN capability from

sleep mode. When the MAX13041 detects two domi-

nant bus states, each followed by a recessive state

(Figure 5), the MAX13041 sets the wake-up flag and

enters an operating mode determined by the state of

EN and STB. Each CAN logic state must be at least 5Âµs

in duration. This wake-up detection criterion serves to

prevent unintentional wake-up events due to bus faults

such as VBAT to CANH or an open circuit on CANL. At

higher data rates (>125kbit/s), wake-up can not be

guaranteed for a single, arbitrary CAN data frame. Two

or more consecutive arbitrary CAN data frames may be

required to ensure a successful wake-on-CAN event.

External-Voltage Regulator Control

MAX13041 controls one or more external voltage regu-

lators through INH, a VBAT-referenced, open-drain out-

put. When INH is logic-high, any external voltage

regulators are active and power is supplied to the

node. When INH is high-impedance, the typical pull-

down characteristic of the voltage-regulator inhibit input

pulls INH to a logic-low and disables the external volt-

age regulator(s).

Fault Protection & Fail-Safes

The MAX13041 features Â±80V tolerance on CAN bus

lines CANH, CANL, and SPLIT. Up to +76V operation is

possible on VBAT, allowing for use in +42V automotive

applications. Additionally, the device detects local and

remote bus failures and features fail-safe modes to

prevent damage to the device or interference with CAN

bus communication.

The MAX13041 detects five different local faults. When

any local fault is detected, the local failure flag is set.

Additionally, for faults other than bus dominant clamp-

ing, the transmitter is disabled to prevent possible dam-

age to the device. The transmitter remains disabled

until the local failure flag is cleared.

TXD Dominant Clamping

An extended logic-low level on TXD due to hardware or

software failure would ordinarily clamp the CAN bus to

a dominant state, blocking communication on the entire

bus. This condition is prevented by the TXD dominant

time-out feature. If TXD is held low for longer than

tDOM(TXD), the local failure flag is set and the transmit-

ter is disabled until the local failure flag is cleared. The

TXD time-out value limits the minimum allowable bit rate

to 40kbps.

RXD Recessive Clamping

If a hardware failure clamps RXD to a logic-high level,

the protocol controller assumes the CAN bus is in a

recessive state at all times. This has the undesirable

effect that the protocol controller assumes the bus is

clear and may initiate messages that would interfere with

ordinary communication. This local failure is detected by

checking the state of RXD when the CAN bus is in a

dominant state. If RXD does not reflect the state of the

CAN bus, the local failure flag is set and the transmitter is

disabled until the local failure flag is cleared.

TXD-to-RXD Short-Circuit Detection

A short-circuit between TXD and RXD forces the bus

into a permanent dominant state upon the first transmis-

sion of a dominant bit because normally the low-side

driver of RXD is stronger than the microcontroller high-

side driver of TXD. The MAX13041 detects this condi-

tion and prevents the resulting bus failure by setting the

local failure flag and disabling the transmitter. The

transmitter remains disabled until the local failure flag is

cleared.

Bus Dominant Clamping

A short-circuit fault from the CAN bus to VBAT, VCC, or

GND could produce a differential voltage between

CANH and CANL greater than the receiver threshold,

resulting in a dominant bus state. If the bus state is

clamped dominant for longer than tDOM(BUS), the local

failure flag is set. The transmitter is not disabled by this

fault and the local failure flag is cleared as soon as the

bus state becomes recessive.

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