ATA663454-GDQW - ATMEL - Datasheet.Directory

9232H-AUTO-09/14

Features

●Supply voltage up to 40V

●Operating voltage VVS = 5V to 28V

●Supply current

●Sleep mode: typically 10µA

●Silent mode: typically 47µA

●Very low current consumption at low supply voltages (2V < VVS < 5.5V):

typically 150µA

●Linear low-drop voltage regulator, 85mA current capability:

●MLC (multi-layer ceramic) capacitor with 0Ω ESR

●Normal, fail-safe, and silent mode

●Atmel ATA663454: VCC = 5.0V ±2%

●Atmel ATA663431: VCC = 3.3V ±2%

●Sleep mode: VCC is switched off

●VCC undervoltage detection with open drain reset output (NRES, 4ms reset time)

●Voltage regulator is short-circuit and over-temperature protected

●Adjustable watchdog time via external resistor

●Negative trigger input for watchdog

●Limp Home watchdog failure output

●LIN physical layer according to LIN 2.0, 2.1, 2.2, 2.2A and SAEJ2602-2

●Bus pin is overtemperature and short-circuit protected versus GND and battery

●High-side switch

●Wake-up capability via LIN Bus (100µs dominant), WKin pin and CL15 pin

●Wake-up source recognition

●TXD time-out timer

●Advanced EMC and ESD performance

●Fulfills the OEM “Hardware Requirements for LIN in Automotive Applications

Rev.1.3”

●Interference and damage protection according to ISO7637

●Qualified according to AEC-Q100

●Package: DFN16 with wettable flanks (Moisture Sensitivity Level 1)

Note: 1. LIN SBC: LIN system basis chip

ATA663431/ATA663454

LIN SBC(1) including LIN Transceiver, Voltage Regulator,

Window Watchdog and High-side Switch

DATASHEET

ATA663431/ATA663454 [DATASHEET]

9232H–AUTO–09/14

1. Description

Designed in compliance with LIN specifications 2.0, 2.1, 2.2, 2.2A and SAEJ2602-2, the Atmel® ATA663431/ATA663454 is a

new generation of system basis chips with a fully integrated LIN transceiver, a low-drop voltage regulator (3.3V/5V/85mA), a

window watchdog, and a high-side switch. This combination makes it possible to develop simple, but powerful, slave nodes

in LIN-bus systems. Atmel ATA663431/ATA663454 is designed to handle low-speed data communication in vehicles (such

as in convenience electronics). Improved slope control at the LIN driver ensures secure data communication up to 20Kbaud.

The bus output is designed to withstand high voltage. Sleep mode and silent mode guarantee a minimized current

consumption even in the case of a floating or short-circuited LIN bus.

Figure 1-1. Block Diagram

TXD

RXD

VCC

NRES

GND

Short-circuit and

overtemperature

protection

Voltage regulator

Normal/Silent/

Fail-safe Mode

3.3V/5V

Control

unit

Normal and

Fail-safe

Mode

RF-filter

High Side Switch

LIN

VS15

WKin

TXD

Time-Out

Timer

Slew rate control

Undervoltage reset

Sleep

mode

VCC

switched

off

Wake-up module

Atmel ATA663431/ATA663454

Receiver

VCC

Window Watchdog

Watchdog Oscillator

CL15

WDOSC

NTRIG

MODE

VCC

HSout

HSin

HV Input

(negative edge)

HV Input

(positive edge)

VCC

ATA663431/ATA663454 [DATASHEET]

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2. Pin Configuration

Figure 2-1. Pinning DFN16

Table 2-1. Pin Description

Pin Symbol Function

1RXD Receive data output

2EN Enable normal mode if the input is high

3NRES VCC undervoltage output, open drain, low at reset

4TXD Transmit data input

5NTRIG Low-level watchdog trigger input from microcontroller; if not needed, connect to VCC

6MODE Control input for watchdog. Low: watchdog is on. High: watchdog is off

7WDOSC Connection for external resistor to set the watchdog frequency

8HSin High-side control input

9HSout High-side switch output

10 LH Failure output of the watchdog (Limp Home), open drain

11 CL15 Ignition detection (edge sensitive); if not needed, connect to GND

12 WKin High-voltage input for local wake-up request; if not needed, connect directly to VS

13 GND Ground

14 LIN LIN bus line input/output

15 VS Supply voltage

16 VCC Output voltage regulator 3.3V/5V/85mA

Backside Heat slug, internally connected to GND

VCC

Atmel

ATA663431

ATA663454

DFN16

3 x 5.5mm

LIN

GND

RXD

NRES

TXD

WKin

CL15

WDOSC

HSout

MODE

NTRIG

HSin

116

ATA663431/ATA663454 [DATASHEET]

9232H–AUTO–09/14

3. Pin Description

3.1 Supply Pin (VS)

LIN operating voltage is VVS = 5V to 28V. In order to avoid false bus messages, undervoltage detection is implemented to

disable transmission if VVS falls below VVS_th_N_F_down. After switching on VVS, the IC starts in fail-safe mode and the voltage

regulator is switched on.

The supply current in sleep mode is typically 10µA and 47µA in silent mode.

3.2 Ground Pin (GND)

The IC does not affect the LIN bus in the event of GND disconnection. It can handle ground shifts of up to 11.5% with respect

to VVS.

3.3 Voltage Regulator Output Pin (VCC)

The internal 3.3V/5V voltage regulator is capable of driving loads up to 85mA, supplying the microcontroller and other ICs on

the PCB, and is protected against overload by means of current limitation and overtemperature shutdown. Furthermore, the

output voltage is monitored and causes a reset signal at the NRES output pin if it drops below a defined threshold

VVCC_th_uv_down.

3.4 Undervoltage Reset Output Pin (NRES)

If the VVCC voltage falls below the undervoltage detection threshold VVCC_th_uv_down, NRES switches to low after tres_f. Even if

VVCC = 0V, the NRES stays low because it is internally driven from the VS voltage. If VS voltage ramps down, NRES stays

low until VVS < 1.5V and then becomes high-impedant.

The undervoltage delay implemented keeps NRES low for tReset = 4ms after VVCC reaches its nominal value.

3.5 Bus Pin (LIN)

A low-side driver is implemented with internal current limitation and thermal shutdown as well as an internal pull-up resistor

in compliance with LIN specification 2.x. The voltage range is from –27V to +40V. This pin exhibits no reverse current from

the LIN bus to VS, even in the event of a GND shift or supply disconnection. The LIN receiver thresholds comply with the LIN

protocol specification.

The fall time (transition from recessive to dominant state) and the rise time (transition from dominant to recessive state) are

slope-controlled.

During a short-circuit at the LIN pin to VBAT the output limits the output current to IBUS_LIM. Due to the power dissipation, the

chip temperature exceeds TLINoff and the LIN output is switched off. The chip cools down and, after a hysteresis of Thys,

switches the output on again. RXD stays on high because LIN is high. During LIN overtemperature switch-off, the VCC

regulator works independently.

During a short circuit from LIN to GND the IC can be switched into sleep or silent mode and even in this case the current

consumption is lower than 100µA in sleep mode and lower than 120µA in silent mode. If the short circuit disappears, the IC

starts with a remote wake-up.

The reverse current is < 2µA at pin LIN during loss of VBat. This is optimal behavior for bus systems where some slave nodes

are supplied from battery or ignition.

ATA663431/ATA663454 [DATASHEET]

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3.6 Bus Data Input/Output (TXD)

In normal mode the TXD pin is the microcontroller interface for controlling the state of the LIN output. TXD must be pulled to

ground in order to drive the LIN bus low. If TXD is high or unconnected (internal pull-up resistor), the LIN output transistor is

turned off and the bus is in the recessive state. If the TXD pin stays at GND level while switching into normal mode, it must

be pulled to high longer than 10µs before the LIN driver can be activated. This feature prevents the bus line from being

driven unintentionally to dominant state after normal mode has been activated (also in the case of a short circuit at TXD to

GND). If TXD is short-circuited to GND, it is possible to switch to sleep mode via the EN pin after t > tdom.

In fail-safe mode this pin is used as an output and signals the fail-safe source.

An internal timer prevents the bus line from being driven permanently in the dominant state. If TXD is forced to low longer

than tdom > 20ms, the LIN bus driver is switched to the recessive state. Nevertheless, when switching to sleep mode, the

actual level at the TXD pin is relevant.

To reactivate the LIN bus driver, TXD needs to be set high for at least tDTOrel (min 10µs).

3.7 Bus Data Output Pin (RXD)

In normal mode this pin reports the state of the LIN bus to the microcontroller. LIN high (recessive state) is indicated by a

high level at RXD; LIN low (dominant state) is indicated by a low level at RXD. The output is a push-pull stage switching

between VCC and GND. The AC characteristics are measured with an external load capacitor of 20pF.

In silent mode the RXD output switches to high.

3.8 Enable Input Pin (EN)

The enable input pin controls the operating mode of the device. If EN is high, the circuit is in normal mode, with the TXD to

LIN and the LIN to RXD the transmission paths both active. The VCC voltage regulator operates with 3.3V/5V/85mA output

capability.

If EN is switched to low while TXD is still high, the device is forced into silent mode. No data transmission is possible and the

current consumption is reduced to IVSsilent typ. 47µA. The VCC regulator maintains full functionality.

If EN is switched to low while TXD is low, the device is forced into sleep mode. This disables data transmission and the

voltage regulator is switched off.

Pin EN provides a pull-down resistor to force the transceiver into recessive mode if EN is disconnected.

3.9 Wake Input Pin (WKin)

The WKin pin is a high-voltage input used for waking up the device from sleep mode or silent mode. It is usually connected

to an external switch in the application to generate a local wake-up. A pull-up current source with typically 10µA is

implemented. The voltage threshold for a wake-up signal is typically 2V below VVS. If the WKin pin is not needed in the

application, it can be connected directly to the VS pin.

3.10 CL15 Pin

The CL15 pin is a high-voltage input that can be used to wake up the device from sleep mode or silent mode. It is an edge-

sensitive pin (low to-high transition). Thus, even if the CL15 pin is at high voltage (VCL15 > VCL15H), it is possible to switch the

IC into sleep mode or silent mode. It is usually connected to the ignition for generating a local wake-up in the application if

the ignition is switched on. The CL15 pin should be tied directly to ground if not needed. A debounce timer with a value

tdbCL15 of typically 100μs is implemented. To protect this pin against transients, a serial resistor with 10kΩ and a ceramic

capacitor with 47nF are recommended. With this RC combination you can increase the CL15 wake-up time.

3.11 WDOSC Output Pin

The WDOSC output pin provides a typical voltage of 1.23V intended to supply an external resistor with values between 34kΩ

and 120kΩ. The value of the resistor adjusts the watchdog oscillator frequency to provide a certain range of time windows.

If the watchdog is disabled, the output voltage is switched off and the pin can either be tied to VCC or left open.

ATA663431/ATA663454 [DATASHEET]

9232H–AUTO–09/14

3.12 NTRIG Input Pin

The NTRIG input pin is the trigger input for the window watchdog. A pull-up resistor is implemented. A falling edge triggers

the watchdog. The trigger signal (low) must exceed a minimum time of ttrigmin to generate a watchdog trigger and avoid false

triggers caused by transients.

3.13 Mode Input Pin (MODE)

Connect the MODE pin directly or via an external resistor to GND for normal watchdog operation. To debug the software of

the connected microcontroller, connect the MODE pin to VCC and the watchdog is switched off. For fail-safe reasons, the

MODE pin has a self-holding function, pulling the input to ground (i.e., watchdog enabled) in case of an open connection.

Note: If you do not use the watchdog, connect the mode pin directly to VCC.

3.14 Limp Home Watchdog Failure Output (LH)

The LH output pin indicates a failure of the watchdog. It is realized as a high-voltage open drain NMOS structure. During

power up or after a wake-up from sleep mode the LH output is switched off. As the watchdog is only working in normal and

fail-safe mode, the state of the LH output transistor can change only in these two modes. In silent mode the LH output

remains in the same state as it was before switching into silent mode.

If a watchdog reset occurs, the LH output transistor switches on immediately, and it switches off only after three correct

consecutive watchdog trigger pulses have been occurred at the NTRIG pin.

3.15 High-side Switch Pins (HSout, HSin)

This high-side switch is designed for low-power loads such as LEDs, sensors or a voltage divider for measuring the supply

voltage. It is functional in all operating modes of the chip except for sleep mode. Its structure is connected to the VS supply

pin. This pin is short-circuit protected and also protected against overheating, whereas the protective shutdown is

debounced and latched. In other words, after a protective shutdown of the output switch, the control line HSin has to go to

low level first before the output can be restarted again.

The high-side switch is controlled via the low-voltage input pin HSin. If the input is high, the output is switched on. For fail-

safe reasons, the HSin input is equipped with a pull-down resistor to GND. This keeps the high-side switch off in case of a

missing connection from the controller.

Please note that in case of a disconnected system ground, the module can be supplied via the connected load on the high-

side output and an internal ESD structure. This is the case if the load has a different ground connection than the PCB. See

also the “Absolute Maximum Ratings” section for current limits in such cases.

ATA663431/ATA663454 [DATASHEET]

9232H–AUTO–09/14

4. Functional Description

4.1 Physical Layer Compatibility

Because the LIN physical layer is independent of higher LIN layers (such as the LIN protocol layer), all nodes with a LIN

physical layer according to revision 2.x can be mixed with LIN physical layer nodes found in older versions (i.e., LIN 1.0, LIN

1.1, LIN 1.2, LIN 1.3) without any restrictions.

4.2 Operating Modes

Figure 4-1. Operating Modes

a: VS > VVS_th_U_F_up (2.4V)

b: VS < VVS_th_U_down (1.9V)

c: Bus wake-up event (LIN)

e: VS < VVS_th_N_F_down (3.9V)

f: VS > VVS_th_F_N_up (4.9V)

d: VCC < VVCC_th_uv_down (2.4V/4.2V) or WD-Reset

EN = 1

EN = 0

Go to sleep

command

Go to silent

command

EN = 0

TXD = 0

c & f

g & f

EN = 0

TXD = 0

EN = 0

TXD = 1

EN = 1

& f

TXD = 1

& f

Fail-safe Mode

VCC: ON

VCC monitor active

Communication: OFF

Wake-up Signaling

Undervoltage Signaling

Watchdog: ON

Normal Mode

VCC: ON

VCC monitor active

Communication: ON

Watchdog: ON

Sleep Mode

VCC: OFF

Communication: OFF

Watchdog: OFF

Unpowered Mode

All circuitry OFF

Silent Mode

VCC: ON

VCC monitor active

Communication: OFF

Watchdog: OFF

c & f,

g & f,

EN = 1

& f

& f & d

& f

g: Local wake-up event (WKin or CL15)

Table 4-1. Operating Modes (Mode Pin Is Always Low)

Operating

Modes Transceiver

Voltage

Regulator Watchdog LH

High-Side

Output LIN TXD RXD

Fail-safe OFF ON ON WD

dependent HSin-dependent Recessive Signaling fail-safe

sources (see Table 4-2)

Normal ON ON ON WD

dependent HSin-dependent TXD

dependent

Follows data

transmission

Silent OFF ON OFF Remains in

previous state HSin-dependent Recessive High High

Sleep/Unpowered OFF OFF OFF OFF OFF Recessive Low Low

ATA663431/ATA663454 [DATASHEET]

9232H–AUTO–09/14

4.2.1 Normal Mode

This is the normal transmission and receiving mode of the LIN interface. The VCC voltage regulator works with 3.3V/5V

output voltage. The watchdog needs a trigger signal from NTRIG to avoid resets at NRES. If NRES switches to low, the IC

changes its state to fail-safe mode.

4.2.2 Silent Mode

A falling edge at EN while TXD is high switches the IC into silent mode. The TXD signal has to be logic high during the mode

select window. The transmission path is disabled in silent mode. The voltage regulator is active. The overall supply current

from VBAT is a combination of the IVSsilent of typ. 47µA plus the VCC regulator output current IVCC.

Figure 4-2. Switching to Silent Mode

In silent mode, the internal slave termination between the LIN pin and VS pin is disabled to minimize current consumption in

case the LIN pin is short-circuited to GND. Only a weak pull-up current (typically 10µA) is present between the LIN pin and

the VS pin. Silent mode can be activated regardless of the current level on the LIN pin or WKin pin.

If an undervoltage condition occurs, NRES is switched to low and the Atmel ATA663431/ATA663454 changes its state to

fail-safe mode.

Delay time silent mode

td_silent = maximum 20µs

Mode select window

LIN switches directly to recessive mode

td = 3.2µs

LIN

VCC

NRES

TXD

Normal Mode Silent Mode

ATA663431/ATA663454 [DATASHEET]

9232H–AUTO–09/14

4.2.3 Sleep Mode

A falling edge at EN while TXD is low switches the IC to sleep mode. The TXD signal has to be logic low during the mode

select window.

Figure 4-3. Switching to Sleep Mode

In order to avoid any influence on the LIN pin while switching into sleep mode, it is possible to switch the EN to low up to

3.2µs earlier than the TXD. The best and easiest way is to generate two simultaneous falling edges at TXD and EN.

The transmission path is disabled in sleep mode. Supply current from VBAT is typically IVSsleep = 10µA. The VCC regulator is

switched off; NRES and RXD are low. The internal slave termination between the LIN and VS pins is disabled to minimize

current consumption in case the LIN pin is short-circuited to GND. Only a weak pull-up current (typically 10µA) between the

LIN pin and VS pin is present. Sleep mode can be activated independently from the current level on the LIN pin. A voltage

less than the LIN pre-wake detection VLINL at the LIN pin activates the internal LIN receiver and starts the wake-up detection

timer.

If TXD is short-circuited to GND, it is possible to switch to sleep mode via EN after t > tdom.

Delay time sleep mode

td_sleep = maximum 20µs

LIN switches directly to recessive mode

td = 3.2µs

LIN

VCC

NRES

TXD

Sleep Mode

Normal Mode

Mode select window

ATA663431/ATA663454 [DATASHEET]

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4.2.4 Fail-Safe Mode

The device automatically switches to fail-safe mode at system power-up. The voltage regulator and the watchdog are

switched on. The NRES output remains low for tres = 4ms and resets the microcontroller. LIN communication is switched off.

The IC stays in this mode until EN is switched to high. The IC then changes to normal mode. A low at NRES switches the IC

directly into fail-safe mode. During fail-safe mode the TXD pin is an output and together with the RXD output pin transmits a

signal indicating the fail-safe source.

If the device enters fail-safe mode coming from normal mode (EN=1) due to a VVS undervoltage condition

(VVS <V

VS_th_N_F_down), it is possible to switch to sleep mode or silent mode through a falling edge at the EN input. The

current consumption can be reduced further with this feature.

A wake-up event from either silent mode or sleep mode is indicated to the microcontroller using the two pins RXD and TXD.

A VVS undervoltage condition is also indicated at these two pins. The coding is shown in Table 4-2.

A wake-up event switches the IC to fail-safe mode.

Table 4-2. Signaling in Fail-safe Mode

Fail-Safe Sources TXD RXD

LIN wake-up (LIN pin) Low Low

Local wake-up (WKin pin or CL15 pin) Low High

VVS_th_N_F_down (battery) undervoltage detection (VVS <3.9V) High Low

ATA663431/ATA663454 [DATASHEET]

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4.3 Wake-up Scenarios from Silent Mode or Sleep Mode

4.3.1 Remote Wake-up via LIN Bus

4.3.1.1 Remote Wake-up from Silent Mode

A remote wake-up from silent mode is only possible if TXD is high. A voltage less than the LIN pre-wake detection VLINL at

the LIN pin activates the internal LIN receiver and starts the wake-up detection timer. A falling edge at the LIN pin followed

by a dominant bus level maintained for a given time period (> tbus) and the following rising edge at the LIN pin (see

Figure 4-4) result in a remote wake-up request. The device switches from silent mode to fail-safe mode, the VCC voltage

regulator remains activated and the internal LIN slave termination resistor is switched on. The remote wake-up request is

indicated by a low level at the RXD and TXD pins (strong pull-down at TXD). EN high can be used to switch directly to

normal mode.

Figure 4-4. LIN Wake-up from Silent Mode

Low

Fail-safe Mode Normal Mode

EN High

High

NRES

VCC

RXD

LIN bus

Bus wake-up filtering time

tbus

HighTXD High

Watchdog Watchdog off Start Watchdog lead time td

Low (strong pull-down)

ATA663431/ATA663454 [DATASHEET]

9232H–AUTO–09/14

4.3.1.2 Remote Wake-up from Sleep Mode

A voltage less than the LIN pre-wake detection VLINL at the LIN pin activates the internal LIN receiver and starts the wake-up

detection timer.

A falling edge at the LIN pin followed by a dominant bus level maintained for a given time period (> tbus) and a subsequent

rising edge at the LIN pin results in a remote wake-up request. The device switches from sleep mode to fail-safe mode.

The VCC regulator is activated, and the internal LIN slave termination resistor is switched on. The remote wake-up request

is indicated by a low level at RXD and TXD (strong pull-down at TXD).

EN high can be used to switch directly from sleep/silent to fail-safe mode. If EN is still high after VCC ramp-up and the

undervoltage reset time, the IC switches to normal mode.

Figure 4-5. LIN Wake-up from Sleep Mode

tVCC

Off state

On state

Low

Fail-safe Mode Normal Mode

EN High

Microcontroller

start-up time delay

Reset

time

Low (strong pull-down)

Low

NRES

VCC

RXD

LIN bus

Bus wake-up filtering time

tbus

High

TXD

High

Watchdog off

Watchdog Start watchdog lead time td

ATA663431/ATA663454 [DATASHEET]

9232H–AUTO–09/14

4.3.2 Local Wake-up via WKin Pin

A falling edge at the WKin pin followed by a low level maintained for a given time period (> tWKin) results in a local wake-up

request. The device switches to fail-safe mode. The internal slave termination resistor is switched on. The local wake-up

request is indicated by a low level at the TXD pin to generate an interrupt for the microcontroller. When the WKin pin is low,

it is possible to switch to silent mode or sleep mode via the EN pin. In this case, the wake-up signal has to be switched to

high > 10µs before the negative edge at WKin starts a new local wake-up request.

Figure 4-6. Local Wake-up via WKin pin from Sleep Mode

tVCC

Off state

On state

High

Fail-safe Mode Normal Mode

EN High

Microcontroller

start-up time delay

Reset

time

Low (strong pull-down)

Low

NRES

VCC

RXD

WKin

TXD

Wake filtering time

tWKin

State change

Watchdog off

Watchdog Start watchdog lead time td

ATA663431/ATA663454 [DATASHEET]

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Figure 4-7. Local Wake-up via WKin pin from Silent Mode

4.3.3 Local Wake-up via CL15

A voltage on pin CL15 above VCL15H for at least tdbCL15 results in a local wake-up request. The device switches to fail-safe

mode. The internal slave termination resistor is switched on. The local wake-up request is indicated by a low level at the TXD

pin to generate an interrupt for the microcontroller. Even when the CL15 pin is high, it is possible to switch to silent mode or

sleep mode via the EN pin. In this case, the wake-up signal at CL15 has to be switched to low > 10µs before the rising edge

at CL15 starts a new local wake-up request.

4.3.4 Wake-up Source Recognition

The device can distinguish between different wake-up sources (see Table 4-3). The wake-up source can be read on the TXD

and RXD pin in fail-safe mode. These flags are immediately reset if the microcontroller sets the EN pin to high and the IC is

in normal mode.

Fail-safe Mode Normal Mode

EN High

High

NRES

VCC

RXD

WKin

TXD Low (strong pull-down)

Wake filtering time

tWKin

State change

Watchdog off

Watchdog Start watchdog lead time td

Table 4-3. Signaling in Fail-safe Mode

Fail-Safe Sources TXD RXD

LIN wake-up (LIN pin) Low Low

Local wake-up (WKin pin or CL15 pin) Low High

VVS_th_N_F_down (battery) undervoltage detection (VVS <3.9V) High Low

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4.4 Behavior under Low Supply Voltage Conditions

After the battery voltage has been connected to the application circuit, the voltage at the VS pin increases according to the

block capacitor (see Figure 4-12 on page 17). If VVS is higher than the minimum VVS operation threshold VVS_th_U_F_up (typ.

2.25V), the IC mode changes from unpowered mode to fail-safe mode. As soon as VVS exceeds the undervoltage threshold

VVS_th_F_N_up (typ. 4.6V), the LIN transceiver can be activated. The VCC output voltage reaches its nominal value after tVCC.

This parameter depends on the externally applied VCC capacitor and the load. The NRES output is low for the reset time

delay treset. No mode change is possible during this time treset.

The behavior of VCC, NRES and VS is shown in following diagrams (ramp-up and ramp-down):

Figure 4-8. VCC and NRES versus VS (Ramp-up) for ATA663431

Figure 4-9. VCC and NRES versus VS (Ramp-down) for ATA663431

V (V)

VS (V)

0.0

0.5

1.0

1.5

2.0

2.5

3.0

3.5

4.0

4.5

5.0

5.5

6.0

6.5

7.0

0.0 0.5 1.0 1.5 2.0 2.5 3.0 3.5 4.0 4.5 5.0 5.5 6.0 6.5 7.0

VCC NRES

V (V)

VS (V)

0.0

0.5

1.0

1.5

2.0

2.5

3.0

3.5

4.0

4.5

5.0

5.5

6.0

6.5

7.0

0.00.51.01.52.02.53.03.54.04.55.05.56.06.57.0

VCC

NRES

ATA663431/ATA663454 [DATASHEET]

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Figure 4-10. VCC and NRES versus VS (Ramp-up) for ATA663454

Figure 4-11. VCC and NRES versus VS (Ramp-down) for ATA663454

Please note that the upper graphs are only valid if the VVS ramp-up and ramp-down time is much slower than the VCC ramp-

up time tVcc and the NRES delay time treset.

If during sleep mode the voltage level of VVS drops below the undervoltage detection threshold VVS_th_N_F_down (typ. 4.3V),

the operating mode is not changed and no wake-up is possible. Only if the supply voltage on pin VS drops below the VVS

operation threshold VVS_th_U_down (typ. 2.05V) does the IC switch to unpowered mode.

If during silent mode the VCC voltage drops below the VCC undervoltage threshold VVCC_th_uv_down the IC switches into fail-

safe mode. If the supply voltage on pin VS drops below the VVS operation threshold VVS_th_U_down (typ. 2.05V), does the IC

switch to unpowered mode.

If during normal mode the voltage level on pin VS drops below the VVS undervoltage detection threshold VVS_th_N_F_down (typ.

4.3V), the IC switches to fail-safe mode. This means the LIN transceiver is disabled in order to avoid malfunctions or false

bus messages. The voltage regulator remains active.

For ATA663431: In this undervoltage situation, it is possible to switch the device into sleep mode or silent mode

through a falling edge at the EN input pin. This feature ensures that it is always possible to switch to these two current

saving modes so that current consumption can be reduced even further.

When the VCC voltage drops below the VCC undervoltage threshold VVCC_th_uv_down (typ. 2.6V) the IC switches into

fail-safe mode.

For ATA663454: Because of the VCC undervoltage condition in this situation, the IC is in fail-safe mode and can be

switched into sleep mode only.

Only when the supply voltage VVS drops below the operation threshold VVS_th_U_down (typ. 2.05V) does the IC switch

into unpowered mode.

The current consumption of the ATA663431/ATA663454 in silent mode is always below 200µA, even when the supply

voltage VVS is lower than the regulator’s nominal output voltage VCC.

V (V)

VS (V)

0.0

0.5

1.0

1.5

2.0

2.5

3.0

3.5

4.0

4.5

5.0

5.5

6.0

6.5

7.0

0.0 0.5 1.0 1.5 2.0 2.5 3.0 3.5 4.0 4.5 5.0 5.5 6.0 6.5 7.0

NRES

VCC

V (V)

VS (V)

0.0

0.5

1.0

1.5

2.0

2.5

3.0

3.5

4.0

4.5

5.0

5.5

6.0

6.5

7.0

0.00.51.01.52.02.53.03.54.04.55.05.56.06.57.0

NRES

VCC

ATA663431/ATA663454 [DATASHEET]

9232H–AUTO–09/14

4.5 Voltage Regulator

Figure 4-12. VCC Voltage Regulator: Supply Voltage Ramp-up and Ramp-down

The voltage regulator needs an external capacitor for compensation and to smooth the disturbances from the

microcontroller. It is recommended to use a MLC capacitor with a minimum capacitance of 1.8µF together with a 100nF

ceramic capacitor. Depending on the application, the values of these capacitors can be modified by the customer.

When the Atmel ATA663431/ATA663454 is being soldered onto the PCB, it is mandatory to connect the heat slug with a

wide GND plate on the printed board to achieve a good heat sink.

The main power dissipation of the IC is created from the VCC regulator output current IVCC, which is needed for the

application. Figure 4-13 shows the safe operating area of the Atmel ATA663431/ATA663454 without considering any output

current of the high-side output HSOUT.

Figure 4-13. Power Dissipation: Safe Operating Area: Regulator’s Output Current IVCC versus Supply Voltage VVS at

Different Ambient Temperatures (Rthja = 45K/W assumed)

12V

5.0V/3.3V

4.8V/2.9V

5.0V/3.3V

VCC

tVCC

tReset

2.4V

tres_f

NRES

VVS_th_N_f_down

VVS [V]

I_Vcc [mA]

Tamb = 125°C

Tamb = 115°C

Tamb = 105°C

Tamb = 95°C

Tamb = 85°C

5 6 7 8 9 1011121314 15161718

ATA663431/ATA663454 [DATASHEET]

9232H–AUTO–09/14

4.6 Watchdog

The watchdog anticipates a trigger signal from the microcontroller at the NTRIG (negative edge) input within a time window

of twd. The trigger signal must exceed a minimum time of ttrigmin > 200ns. If a trigger signal is not received, a reset signal is

generated at output NRES and the LH output transistor switches on. The timing basis of the watchdog is provided by the

internal oscillator. Its time period, tosc, is adjustable via the external resistor RWDOSC (34kΩ to 120kΩ). During silent or sleep

mode the watchdog is switched off to reduce current consumption. The minimum time for the first watchdog pulse is required

after the undervoltage reset at NRES disappears, it is defined as lead time td. After wake-up from sleep mode, the lead time

td starts with the rising edge at the NRES output. After a wake-up from silent mode, the lead time td starts with the falling

edge at the TXD pin.

The Limp Home output LH is a high voltage NMOS open drain structure which is signaling watchdog failures. It works

independently of the VCC voltage. So it is possible to switch on some external devices in the case of a watchdog failure

independent from the microcontroller and the VCC voltage. During power up or after a wake-up from sleep mode the LH

output is switched off. If a watchdog reset occurs, the LH output transistor switches on immediately, and it switches off only

after three correct consecutive watchdog trigger pulses have been occurred at the NTRIG pin.

As the watchdog is only working in normal and fail-safe mode, the state of the LH output transistor can change only in these

two modes. In silent mode the LH output remains in the same state as it was before switching into silent mode. When the

watchdog is disabled via a high level at the mode pin or during sleep or unpowered mode, the LH output is also disabled.

The behavior of the LH output when the watchdog is active during fail-safe and normal mode is depicted in Figure 4-14.

Figure 4-14. Limp Home (LH) State Diagram

In sleep mode and unpowered mode the watchdog and therefore the LH output are deactivated. In silent mode the LH output

remains in the same state as it was before switching into silent mode

LH Set Active

State

LH OFF

State

LH Set Active

State

LH Set Active

State

State 0: LH output is switched OFF

State 1: LH output is switched ON

State 2: LH output is switched ON

State 3: LH output is switched ON

wd_reset

Power-up or wake-up

from sleep mode

3rd Trigger

1st Trigger

2nd Trigger

wd_reset

ATA663431/ATA663454 [DATASHEET]

9232H–AUTO–09/14

4.6.1 Typical Timing Sequence with RWDOSC = 51kΩ

The trigger signal twd is adjustable between 20ms and 64ms using the external resistor RWDOSC.

For example, with an external resistor of RWDOSC = 51kΩ ±1%, the typical parameters of the watchdog are as follows:

tosc = (0.405 × RWDOSC – 0.0004 × (RWDOSC)2) × 2 (RWDOSC in kΩ ; tosc in µs)

tosc = 39.3μs due to 51kΩ

td = 3984 × 39.2μs = 154.8ms

t1 = 527 × 39.2μs = 20.6ms

t2 = 553 × 39.3μs = 21.6ms

tnres = constant = 4ms

After ramping up the battery voltage, the 5V regulator is switched on. The reset output NRES stays low for the time treset

(typically 4ms), then it switches to high and the watchdog waits for the trigger sequence from the microcontroller. During

power up or after a wake-up from sleep mode the LH output is switched off. If a watchdog reset occurs, the LH output

transistor switches on immediately, and it switches off only after three correct consecutive watchdog trigger pulses have

been occurred at the NTRIG pin. The lead time, td, follows the reset and is td = 155ms. In this time, the first watchdog pulse

from the microcontroller is required. If the trigger pulse NTRIG occurs during this time, the time t1 starts immediately. If no

trigger signal occurs during the time td, a watchdog reset with tNRES = 4ms will reset the microcontroller after td = 155ms and

the LH output transistor switches on. The times t1 and t2 have a fixed relationship. A trigger signal from the microcontroller is

anticipated within the time frame of t2= 21.6ms. To avoid false triggering from glitches, the trigger pulse must be longer than

ttrigmin > 200ns. This slope serves to restart the watchdog sequence. If the triggering signal fails in this open window t2, the

NRES output is drawn to ground as well as the LH output. A trigger signal during the closed window t1 immediately switches

NRES and LH to low.

Figure 4-15. Timing Sequence with RWDOSC = 51kΩ

tnres = 4ms

Undervoltage Reset Watchdog Reset

treset = 4ms

ttrig > 200ns

t1 = 20.6ms t2 = 21ms

twd

td = 155ms

VCC

3.3V/5V

NTRIG

NRES

t1t2

LH Output Transistor OFF

LH Output

Transistor ON

ATA663431/ATA663454 [DATASHEET]

9232H–AUTO–09/14

4.6.2 Worst-Case Calculation with RWDOSC = 51kΩ

The internal oscillator has a tolerance of 20%. This means that t1 and t2 can also vary by 20%. The worst-case calculation for

the watchdog period twd is calculated as follows. The ideal watchdog time twd is between the maximum t1 and the minimum t1

plus the minimum t2.

t1,min = 0.8 × t1 = 16.5ms, t1,max = 1.2 × t1 = 24.8ms

t2,min = 0.8 × t2 = 17.3ms, t2,max = 1.2 × t2 = 26ms

twdmax = t1,min + t2,min = 16.5ms + 17.3ms = 33.8ms

twdmin = t1,max = 24.8ms

twd = 29.3ms ±4.5ms (±15%)

A microcontroller with an oscillator tolerance of ±15% is sufficient to supply the trigger inputs correctly.

If the WDOSC pin has a short circuit to GND or the external resistor at the WDOSC pin is disconnected, the

watchdog runs with an internal oscillator and guarantees a reset and activation of the LH output.

Table 4-4. Typical Watchdog Timings

RWDOSC

kΩ

Oscillator

Period

tosc/µs

Lead Time

td/ms

Closed

Window

t1/ms

Open Window

t2/ms

Trigger Period from

Microcontroller

twd/ms

Reset Time

tnres/ms

34 13.3 × 2105 14.0 14.7 19.9 4

51 19.61 × 2154.8 20.64 21.67 29.32 4

91 3.54 × 2264.80 35.32 37.06 50.14 4

120 42.84 × 2338.22 45.11 47.34 64.05 4

ATA663431/ATA663454 [DATASHEET]

9232H–AUTO–09/14

5. Absolute Maximum Ratings

Stresses beyond those listed under “Absolute Maximum Ratings” may cause permanent damage to the device. This is a stress rating

only and functional operation of the device at these or any other conditions beyond those indicated in the operational sections of this

specification is not implied. Exposure to absolute maximum rating conditions for extended periods may affect device reliability.

Parameters Symbol Min. Typ. Max. Unit

Supply voltage VVS

- DC voltage

- Ta = 25°C, tPulse ≤ 500ms, IVCC ≤ 85mA

- Ta = 25°C, tPulse ≤ 2min, IVCC ≤ 85mA

VVS

–0.3 +40

+43.5

+28

Logic pin voltage levels (TXD, RXD, EN, HSin,

MODE, WDOSC, NRES, NTRIG) VLOGIC –0.3 +5.5 V

Logic pin output DC currents ILOGIC –5 +5 mA

LIN bus levels VLIN

- DC voltage

- Pulse time ≤ 500ms

VLIN –27 +40

+43.5

VCC

- DC voltage

- DC input current

VVCC

IVCC

–0.3 +5.5

+200

Logic level pins injection currents

- DC currents

- tPulse ≤ 2min

ILOGIC –5

–5

0.1

LH voltage levels VLH –0.3 VVS + 0.3 V

HSout

- DC voltage

- DC output current

- DC current injection levels

VHSout < 0V and VHSout > VVS

VHSout

IHSout

–0.3

–50

–20

VVS + 0.3

+10

CL15 voltage levels

- DC voltage VCL15 –0.3 +40 V

WKin voltage levels

- DC voltage

-Transient voltage according to ISO7637

(coupling 1nF), (with 2.7K serial resistor)

VWKin

–0.3

–150

+40

+100

ESD according to IBEE LIN EMC

Test spec. 1.0 following IEC 61000-4-2

- Pin VS, WKin and LIN to GND

(CL15 and WKin with ext. circuitry according to

applications diagram)

±6 kV

ESD according to ISO10605, with 330pF/330Ω

- Pin HSout (100Ω series resistor, 22nF to

GND) to GND

±6 kV

ESD (HBM following STM5.1 with 1.5kΩ/100pF)

- Pin VS, LIN, WKin, HSout, CL15 to GND ±6 kV

Component level ESD (HBM according to

ANSI/ESD STM5.1)

JESD22-A114

AEC-Q100 (002)

±3 kV

CDM ESD STM 5.3.1 ±750 V

ESD machine model

AEC-Q100-RevF(003) ±100 V

Junction temperature Tj–40 +150 °C

Storage temperature Ts–55 +150 °C

ATA663431/ATA663454 [DATASHEET]

9232H–AUTO–09/14

6. Thermal Characteristics

Parameters Symbol Min. Typ. Max. Unit

Thermal resistance junction to heat slug Rthjc 8K/W

Thermal resistance junction to ambient,

where heat slug is soldered to PCB

according to JEDEC

Rthja 45 K/W

Thermal shutdown of VVCC regulator TVCCoff 150 165 180 °C

Thermal shutdown of LIN output TLINoff 150 165 180 °C

Thermal shutdown of high-side driver TDSoff 150 165 180 °C

Thermal shutdown hysteresis Thys 10 °C

7. Electrical Characteristics

5V < VVS < 28V, –40°C < Tj < 150°C; unless otherwise specified all values refer to GND pins.

No. Parameters Test Conditions Pin Symbol Min. Typ. Max. Unit Type*

1VS pin

1.1 Nominal DC voltage range VS VVS 513.5 28 V A

1.2 Supply current in sleep

mode

Sleep mode

VLIN > VVS – 0.5V

VVS < 14V, T = 27°C

VS IVSsleep 510 15 µA B

Sleep mode

VLIN > VVS – 0.5V

VVS < 14V

VS IVSsleep 311 18 µA A

Sleep mode, VLIN = 0V

Bus shorted to GND

VVS < 14V

VS IVSsleep_short 20 50 100 µA A

1.3 Supply current in silent

mode

Bus recessive

5.5V < VVS < 14V, HS-driver off

without load at VCC

T = 27°C

VS IVSsilent 30 47 58 µA B

Bus recessive

5.5V < VVS < 14V, HS-driver off

without load at VCC

VS IVSsilent 30 50 64 µA A

Bus recessive

VVS < 5.5V, VVCC > VVCC_th_uv

HS-driver off

without load at VCC

VS IVSsilent 30 150 190 µA A

Silent mode

5.5V < VVS < 14V, HS-driver off

without load at VCC

Bus shorted to GND

VS IVSsilent_short 50 90 130 µA A

1.4 Supply current in normal

mode

Bus recessive

VVS < 14V, HS-driver off

without load at VCC, watchdog

on, 51kΩ at WDOSC

VS IVSrec 300 400 500 µA A

Bus recessive

VVS < 14V, HS-driver off

without load at VCC, watchdog

off (VMODE = VVCC)

VS IVSrec 150 250 350 µA A

*) Type means: A = 100% tested, B = 100% correlation tested, C = Characterized on samples, D = Design parameter

ATA663431/ATA663454 [DATASHEET]

9232H–AUTO–09/14

1.5 Supply current in normal

mode

Bus dominant (internal LIN

pull-up resistor active)

VVS < 14V, HS-driver off

without load at VCC, watchdog

on, 51kΩ at WDOSC

VS IVSdom 600 900 1150 µA A

Bus dominant (internal LIN

pull-up resistor active)

VVS < 14V, HS-driver off

without load at VCC, watchdog

off (VMODE = VVCC)

VS IVSdom 500 750 1000 µA A

1.6 Supply current in fail-safe

mode

Bus recessive

5.5V < VVS < 14V, HS-driver off

without load at VCC, watchdog

on, 51kΩ at WDOSC

VS IVSfail 100 200 300 µA A

Bus recessive

5.5V < VVS < 14V, HS-driver off

without load at VCC, watchdog

off (VMODE = VVCC)

VS IVSfail 40 70 100 µA A

Bus recessive

2V < VVS < 5.5V, HS-driver off

without load at VCC

watchdog on, 51kΩ at

WDOSC

VS IVSfail 150 280 320 µA A

Bus recessive

2V < VVS < 5.5V, HS-driver off

without load at VCC

watchdog off (VMODE = VVCC)

VS IVSfail 50 150 200 µA A

1.7

VS undervoltage threshold

(switching from normal

mode to fail-safe mode)

Decreasing supply voltage VS VVS_th_N_F_dow

3.9 4.3 4.7 V A

Increasing supply voltage VS VVS_th_F_N_up 4.1 4.6 4.9 V A

1.8 VS undervoltage hysteresis VS VVS_hys_F_N 0.1 0.25 0.4 V A

1.9

VS operation threshold

(switching to unpowered

mode)

Switch to unpowered mode VS VVS_th_U_down 1.9 2.05 2.3 V A

Switch from unpowered mode

to fail-safe mode VS VVS_th_U_F_up 2.0 2.25 2.4 V A

1.10 VS undervoltage hysteresis VS VVS_hys_U 0.1 0.2 0.3 V A

2RXD output pin

2.1 Low-level output sink

capability

Normal mode,

VLIN =0V, I

RXD =2mA RXD VRXDL 0.2 0.4 V A

2.2 High-level output source

capability

Normal mode

VLIN =V

S, IRXD = –2mA RXD VRXDH

VCC –

0.4V

VCC –

0.2V V A

3TXD input/output pin

3.1 Low-level voltage input TXD VTXDL –0.3 +0.8 V A

3.2 High-level voltage input TXD VTXDH 2VCC +

0.3V V A

3.3 Pull-up resistor VTXD =0V TXD RTXD 40 70 100 kΩA

3.4 High-level leakage current VTXD =V

CC TXD ITXD –3 +3 µA A

7. Electrical Characteristics (Continued)

5V < VVS < 28V, –40°C < Tj < 150°C; unless otherwise specified all values refer to GND pins.

No. Parameters Test Conditions Pin Symbol Min. Typ. Max. Unit Type*

*) Type means: A = 100% tested, B = 100% correlation tested, C = Characterized on samples, D = Design parameter

ATA663431/ATA663454 [DATASHEET]

9232H–AUTO–09/14

3.5 Low-level output sink

current at wake-up request

Fail-safe mode

VLIN = VVS

VWKin = 0V

VTXD = 0.4V

TXD ITXD 22.5 8mA A

4EN input pin

4.1 Low-level voltage input EN VENL –0.3 +0.8 V A

4.2 High-level voltage input EN VENH 2VCC +

0.3V V A

4.3 Pull-down resistor VEN = VVCC EN REN 50 125 200 kΩA

4.4 Low-level input current VEN = 0V EN IEN –3 +3 µA A

5NRES open drain output pin

5.1 Low-level output voltage VVS ≥ 5.5V

INRES =2mA NRES VNRESL 0.2 0.4 V A

5.2 Undervoltage reset time VVS ≥ 5.5V

CNRES = 20pF NRES tReset 2 4 6 ms A

5.3 Reset debounce time for

falling edge

VVS ≥ 5.5V

CNRES = 20pF NRES tres_f 0.5 10 µs A

5.4 Switch-off leakage current VNRES =5.5V NRES INRES_L –3 +3 µA A

6VCC voltage regulator ATA663431

6.1 Output voltage VCC

4V < VVS < 18V

(0mA to 50mA) VCC VVCCnor 3.234 3.366 V A

4.5V < VVS < 18V

(0mA to 85mA) VCC VVCCnor 3.234 3.366 V C

6.2 Output voltage VVCC at low

VVS

3V < VVS < 4V VCC VVCClow VVS – VD3.366 V A

6.3 Regulator drop voltage VVS > 3V, IVCC = –15mA VCC VD1 200 250 mV A

6.4 Regulator drop voltage VVS > 3V, IVCC = –50mA VCC VD2 300 500 mV A

6.5 Line regulation maximum 4V < VVS < 18V VCC VCCline 0.1 0.2 % A

6.6 Load regulation maximum 5mA < IVCC < 50mA VCC VCCload 0.1 0.5 % A

6.7 Output current limitation VVS > 4V VCC IVCClim –180 –120 mA A

6.8 Load capacity MLC capacitor VCC Cload 1.8 2.2 µF D

6.9

VCC undervoltage threshold

(NRES ON)

Referred to VCC

VVS > 4V VCC VVCC_th_uv_dow

2.4 2.6 2.8 V A

VCC undervoltage threshold

(NRES OFF)

Referred to VCC

VVS > 4V VCC VVCC_th_uv_up 2.5 2.7 2.9 V A

6.10 Hysteresis of VCC

undervoltage threshold

Referred to VCC

VVS > 4V VCC VVCC_hys_uv 100 200 300 mV A

6.11 Ramp-up time VVS > 4V to

VCC = 3.3V

CVCC = 2.2µF

Iload = –5mA at VCC VCC tVCC 11.5 ms A

7. Electrical Characteristics (Continued)

5V < VVS < 28V, –40°C < Tj < 150°C; unless otherwise specified all values refer to GND pins.

No. Parameters Test Conditions Pin Symbol Min. Typ. Max. Unit Type*

*) Type means: A = 100% tested, B = 100% correlation tested, C = Characterized on samples, D = Design parameter

ATA663431/ATA663454 [DATASHEET]

9232H–AUTO–09/14

7VCC voltage regulator ATA663454

7.1 Output voltage VCC

5.5V < VVS< 18V

(0mA to 50mA) VCC VVCCnor 4.9 5.1 V A

6V < VVS < 18V

(0mA to 85mA) VCC VVCCnor 4.9 5.1 V C

7.2 Output voltage VCC at low

VVS

4V < VVS < 5.5V VCC VVCClow VVS – VD5.1 V A

7.3 Regulator drop voltage VVS > 4V, IVCC = –20mA VCC VD1 100 200 mV A

7.4 Regulator drop voltage VVS > 4V, IVCC = –50mA VCC VD2 300 500 mV A

7.5 Regulator drop voltage VVS > 3.3V, IVCC = –15mA VCC VD3 150 mV A

7.6 Line regulation maximum 5.5V < VVS < 18V VCC VCCline 0.1 0.2 % A

7.7 Load regulation maximum 5mA < IVCC < 50mA VCC VCCload 0.1 0.5 % A

7.8 Output current limitation VVS > 5.5V VCC IVCClim –180 –120 mA A

7.9 Load capacity MLC capacitor VCC Cload 1.8 2.2 µF D

7.10

VCC undervoltage threshold

(NRES ON)

Referred to VCC

VVS > 4V VCC VVCC_th_uv_dow

4.2 4.4 4.6 V A

VCC undervoltage threshold

(NRES OFF)

Referred to VCC

VVS > 4V VCC VVCC_th_uv_up 4.3 4.6 4.8 V A

7.11 Hysteresis of undervoltage

threshold

Referred to VCC

VVS > 5.5V VCC VVCC_hys_uv 100 200 300 mV A

7.12 Ramp-up time VVS > 5.5V to

VCC = 5V

CVCC = 2.2µF

Iload = –5mA at VCC VCC tVCC 11.5 ms A

LIN bus driver: bus load conditions:

Load 1 (Small): 1nF, 1kΩ; Load 2 (Large): 10nF, 500Ω; CRXD = 20pF, Load 3 (Medium): 6.8nF, 660Ω characterized on samples

10.7 and 10.8 specifies the timing parameters for proper operation at 20kb/s and 10.9kb/s and 10.10kb/s at 10.4kb/s

8.1 Driver recessive output

voltage Load1/Load2 LIN VBUSrec 0.9 × VVS VVS V A

8.2 Driver-dominant voltage VVS = 7V

Rload = 500ΩLIN V_LoSUP 1.2 V A

8.3 Driver-dominant voltage VVS = 18V

Rload = 500ΩLIN V_HiSUP 2 V A

8.4 Driver-dominant voltage VVS = 7V

Rload = 1000ΩLIN V_LoSUP_1k 0.6 V A

8.5 Driver-dominant voltage VVS = 18V

Rload = 1000ΩLIN V_HiSUP_1k 0.8 V A

8.6 Pull-up resistor to VVS The serial diode is mandatory LIN RLIN 20 30 47 kΩA

8.7 Voltage drop at the serial

diodes

In pull-up path with Rslave

ISerDiode = 10mA LIN VSerDiode 0.4 1.0 V D

8.8 LIN current limitation

VBUS = VBat_max

LIN IBUS_LIM 40 120 200 mA A

8.9

Input leakage current at the

receiver including pull-up

resistor as specified

Input leakage current

Driver off

VBUS = 0V

VVS = 12V

LIN IBUS_PAS_dom –1 –0.35 mA A

7. Electrical Characteristics (Continued)

5V < VVS < 28V, –40°C < Tj < 150°C; unless otherwise specified all values refer to GND pins.

No. Parameters Test Conditions Pin Symbol Min. Typ. Max. Unit Type*

*) Type means: A = 100% tested, B = 100% correlation tested, C = Characterized on samples, D = Design parameter

ATA663431/ATA663454 [DATASHEET]

9232H–AUTO–09/14

8.10 Leakage current LIN

recessive

Driver off

8V < VVS < 18V

8V < VBUS < 18V

VBUS ≥ VBat

LIN IBUS_PAS_rec 10 20 µA A

8.11

Leakage current when

control unit disconnected

from ground.

Loss of local ground must

not affect communication in

the residual network

GNDDevice = VVS

VVS = 12V

0V < VBUS < 18V

LIN IBUS_NO_gnd –10 +0.5 +10 µA A

8.12

Leakage current at

disconnected battery. Node

has to sustain the current

that can flow under this

condition. Bus must remain

operational under this

condition.

VVS disconnected

VSUP_Device = GND

0V < VBUS < 18V

LIN IBUS_NO_bat 0.1 2µA A

8.13 Capacitance on the LIN pin

to GND LIN CLIN 20 pF D

9LIN bus receiver

9.1 Center of receiver threshold VBUS_CNT =

(Vth_dom + Vth_rec)/2 LIN VBUS_CNT

0.475 ×

VVS

0.5 ×

VVS

0.525 ×

VVS

V A

9.2 Receiver dominant state VEN = 5V/3.3V LIN VBUSdom –27 0.4 × VVS V A

9.3 Receiver recessive state VEN = 5V/3.3V LIN VBUSrec 0.6 × VVS 40 V A

9.4 Receiver input hysteresis Vhys = Vth_rec – Vth_dom LIN VBUShys

0.028 ×

VVS

0.1 ×

VVS

0.175 ×

VVS

V A

9.5 Pre-wake detection LIN

High-level input voltage LIN VLINH VVS – 2V VVS +

0.3V V A

9.6 Pre-wake detection LIN

Low-level input voltage Activates the LIN receiver LIN VLINL –27 VVS –

3.3V V A

10 Internal timers

10.1 Dominant time for wake-up

via LIN bus VLIN = 0V LIN tbus 50 100 150 µs A

10.2

Time delay for mode change

from fail-safe mode to

normal mode via the EN pin

VEN = 5V/3.3V EN tnorm 515 20 µs A

10.3

Time delay for mode change

from normal mode to Sleep

Mode via the EN pin

VEN = 0V EN tsleep 515 20 µs A

10.4 TXD-dominant time-out time VTXD = 0V TXD tdom 20 40 60 ms A

10.6

Time delay for mode change

from silent mode to normal

mode via the EN pin

VEN = 5V/3.3V EN ts_n 515 40 µs A

10.7 Duty cycle 1

THRec(max) = 0.744 × VVS

THDom(max) = 0.581 × VVS

VVS = 7.0V to 18V

tBit = 50µs

D1 = tbus_rec(min)/(2 × tBit)

LIN D1 0.396 A

7. Electrical Characteristics (Continued)

5V < VVS < 28V, –40°C < Tj < 150°C; unless otherwise specified all values refer to GND pins.

No. Parameters Test Conditions Pin Symbol Min. Typ. Max. Unit Type*

*) Type means: A = 100% tested, B = 100% correlation tested, C = Characterized on samples, D = Design parameter

ATA663431/ATA663454 [DATASHEET]

9232H–AUTO–09/14

10.8 Duty cycle 2

THRec(min) = 0.422 × VVS

THDom(min) = 0.284 × VVS

VVS = 7.6V to 18V

tBit = 50µs

D2 = tbus_rec(max)/(2 × tBit)

LIN D2 0.581 A

10.9 Duty cycle 3

THRec(max) = 0.778 × VVS

THDom(max) = 0.616 × VVS

VVS = 7.0V to 18V

tBit = 96µs

D3 = tbus_rec(min)/(2 × tBit)

LIN D3 0.417 A

10.10 Duty cycle 4

THRec(min) = 0.389 × VVS

THDom(min) = 0.251 × VVS

VVS = 7.6V to 18V

tBit = 96µs

D4 = tbus_rec(max)/(2 × tBit)

LIN D4 0.590 A

10.11 Slope time falling and rising

edge at LIN VVS = 7.0V to 18V LIN tSLOPE_fall

tSLOPE_rise

3.5 22.5 µs A

10.12 TXD release time after

dominant time-out detection TXD tDTOrel 10 20 µs B

11 Receiver electrical AC parameters of the LIN physical layer

LIN receiver, RXD load conditions: CRXD = 20pF

11.1 Propagation delay of

receiver

VVS = 7.0V to 18V

trx_pd = max(trx_pdr , trx_pdf)RXD trx_pd 6µs A

11.2

Symmetry of receiver

propagation delay rising

edge minus falling edge

VVS = 7.0V to 18V

trx_sym = trx_pdr – trx_pdf

RXD trx_sym –2 +2 µs A

12 WKin pin

12.1 High-level input voltage WKin VWKinH VVS – 1V VVS +

0.3V V A

12.2 Low-level input voltage Initializes a wake-up signal WKin VWKinL –1 VVS –

3.3V V A

12.3 WKin pull-up current VVS < 28V, VWKin = 0V WKin IWKin –30 –10 µA A

12.4 High-level leakage current VVS = 28V, VWKin = 28V WKin IWKinL –5 +5 µA A

12.5 Debounce time of low pulse

for wake-up via WKin pin VWKin = 0V WKin tWKin 50 100 150 µs A

13 Watchdog oscillator

13.1 Voltage at WDOSC in

normal or fail-safe mode

IWD_OSC = –200μA

VVS ≥ 4V WDOSC VWDOSC 1.13 1.23 1.33 V A

13.2 Possible values of resistor Resistor ±1% WDOSC RWDOSC 34 120 kΩD

13.3 Oscillator period RWDOSC = 34kΩtOSC 21.3 26.6 31.94 μs A

13.6 Oscillator period RWDOSC = 120kΩtOSC 68.4 85.6 102.8 μs A

13.7 Watchdog lead time after

reset td3948 cycles B

13.8 Watchdog closed window t1527 cycles B

13.9 Watchdog open window t2553 cycles B

13.10 Watchdog reset time NRES NRES tnres 2 4 6 ms B

7. Electrical Characteristics (Continued)

5V < VVS < 28V, –40°C < Tj < 150°C; unless otherwise specified all values refer to GND pins.

No. Parameters Test Conditions Pin Symbol Min. Typ. Max. Unit Type*

*) Type means: A = 100% tested, B = 100% correlation tested, C = Characterized on samples, D = Design parameter

ATA663431/ATA663454 [DATASHEET]

9232H–AUTO–09/14

14 Watchdog trigger input Pin NTRIG

14.1 Low-level voltage input NTRIG VNTRIG_L –0.3 0.3VVCC V A

14.2 High-level voltage input NTRIG VNTRIG_H 0.7VVCC

VVCC +

0.3 V A

14.3 Pull-up resistor VNTRIG =0V NTRIG RNTRIG 125 250 400 K A

14.4 Input leakage current VNTRIG =V

VCC NTRIG INTRIGleakH 1µA A

14.5 Minimum trigger width VNTRIG =V

VCC NTRIG ttrig 200 ns D

15 MODE PIN

15.1 Low-level input voltage MODE VMODE_L –0.3 0.3VVCC V A

15.2 High-level input voltage MODE VMODE_H 0.7VVCC

VVCC +

0.3 V A

15.4 Leakage current VMODE = 0V or VMODE = VVCC MODE IMODE –3 +3 µA A

15.5 MODE pin pull-up current VMODE = 0.7VVCC MODE IMODE_PU –75 –5 µA A

15.6 MODE pin pull-down current VMODE = 0.3VVCC MODE IMODE_PD 575 µA A

16 Limp Home open drain failure output pin LH

16.1 Output drain-to-source on

resistance Tj = 125°C LH RDSon,LH 50 ΩA

16.2 Leakage current VLH < 40V LH Ileak,LH 2µA A

17 HSout pin

17.1 Output drain-to-source on

resistance IHSout = –20mA HSout RDSon,HS 20 ΩA

17.2 Leakage current –0.2V < VHSout < VVS+ 0.2V HSout Ileak,HS 2µA A

17.5 Switch-off slope (fall time)

VVS = 16V

Rload = 560Ω

Cload = 1nF

transition from 80% down to

20% of VVS

HSout tHSslope,fall 0.75 5µs A

17.6 Switch-on slope (rise time)

VVS = 16V

Rload = 560Ω

Cload = 1nF

transition from 20% to 80% of

VVS

HSout tHSslope,rise 0.75 5µs A

17.7 Switch-on delay

VVS = 16V

Rload = 560Ω

Cload = 1nF

time from HSin=HIGH to

VHSout = 50% of VVS

HSout tHSdel 320 µs A

17.8 Switch-off delay

VVS = 16V

Rload = 560Ω

Cload = 1nF

time from HSin=LOW to

VHSout = 50% of VVS

HSout tHSdel 320 µs A

17.9 Short-circuit detection

threshold HSout VSCth_HS VVS – 6V VVS – 2V V A

17.10 Short-circuit deb. time HSout tHS_deb 210 µs A

7. Electrical Characteristics (Continued)

5V < VVS < 28V, –40°C < Tj < 150°C; unless otherwise specified all values refer to GND pins.

No. Parameters Test Conditions Pin Symbol Min. Typ. Max. Unit Type*

*) Type means: A = 100% tested, B = 100% correlation tested, C = Characterized on samples, D = Design parameter

ATA663431/ATA663454 [DATASHEET]

9232H–AUTO–09/14

Figure 7-1. Definition of Bus Timing Characteristics

18 HSin pin

18.1 Low-level voltage input HSin VHSin_L –0.3 0.3VVCC V A

18.2 High-level voltage input HSin VHSin_H 0.7VVCC

VVCC +

0.3 V A

18.3 Pull-down resistor VHSin = VVCC HSin RHSin 50 100 150 kΩA

18.4 Low-level input current VHSin = 0V HSin IHSin –1 +1 µA A

18.5 Maximum switching

frequency Rload = 560ΩHSin fHSin,max 5kHz D

19 CL15 HV input pin

19.1 High Level input voltage Positive edge initiates a local

wake-up CL15 VCL15H 4 V A

19.2 Low level input voltage CL15 VCL15L –1 +2 V A

19.3 Pull-down current VVS < 28V, VCL15 = 28V CL15 ICL15 50 60 µA A

19.4 Internal debounce time Without external capacitor CL15 tdbCL15 50 100 150 µs A

7. Electrical Characteristics (Continued)

5V < VVS < 28V, –40°C < Tj < 150°C; unless otherwise specified all values refer to GND pins.

No. Parameters Test Conditions Pin Symbol Min. Typ. Max. Unit Type*

*) Type means: A = 100% tested, B = 100% correlation tested, C = Characterized on samples, D = Design parameter

TXD

(Input to transmitting node)

(Transceiver supply

of transmitting node)

RXD

(Output of receiving node1)

RXD

(Output of receiving node2)

LIN Bus Signal

Thresholds of

receiving node1

Thresholds of

receiving node2

Bus_rec(max)

rx_pdr(1)

rx_pdf(2)

rx_pdr(2)

rx_pdf(1)

Bus_dom(min)

Bus_dom(max)

Rec(max)

Dom(max)

Rec(min)

Dom(min)

Bus_rec(min)

Bit

ATA663431/ATA663454 [DATASHEET]

9232H–AUTO–09/14

8. Application Circuits

Figure 8-1. Typical Application Circuit

Note: Heat slug must always be connected to GND.

Atmel

ATA663431

ATA663454

DFN16

3 x 5.5

RXD

NRES

TXD

MODE

NTRIG

WDOSC

HSin

VCC

Microcontroller

VCC

VBAT

Master node

pull-up

LIN

GND

220pF

10µF/50V

100nF

47nF

100nF

2.2µF

LIN

GND

WKin (opt.)

CL15 (opt.)

* The MODE pin can be connected directly to GND,

if it is not needed to disable the Watchdog

ES1

WKin

CL15

HSout

GND

R8*

10kΩ

2.7kΩ

1kΩ

51kΩ

9. Ordering Information

Extended Type Number Package Remarks

ATA663431-GDQW DFN16 3.3V LIN system basis chip, Pb-free, 6k, taped and reeled

ATA663454-GDQW DFN16 5V LIN system basis chip, Pb-free, 6k, taped and reeled

ATA663431/ATA663454 [DATASHEET]

9232H–AUTO–09/14

10. Package Information

Package Drawing Contact:

packagedrawings@atmel.com

GPC DRAWING NO.

REV. TITLE

6.543-5168.01-4 1

10/11/13

Package: VDFN_5.5x3_16L

Exposed pad 4.7x1.6

Two Step Singulation process

COMMON DIMENSIONS

(Unit of Measure = mm)

MIN NOM NOTEMAXSymbol

Dimensions in mm

specifications

according to DIN

technical drawings

0.035 0.050.0A1

33.12.9E

0.3 0.350.25b

0.65e

0.4 0.450.35L

1.6 1.71.5E2

4.7 4.84.6D2

5.5 5.65.4D

0.21 0.260.16A3

0.85 0.90.8A

Partially Plated Surface

Z 10:1

PIN 1 ID

Top View

Side View

Bottom View

16 9

XXX

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