NCV7349D13R2G - ON SEMICONDUCTOR

December, 2014 − Rev. 1 1Publication Order Number:

NCV7349/D

NCV7349

High Speed Low Power CAN

Transceiver

Description

The NCV7349 CAN transceiver is the interface between

a controller area network (CAN) protocol controller and the physical

bus. The transceiver provides differential transmit capability to the bus

and differential receive capability to the CAN controller.

The NCV7349 is a new addition to the CAN high−speed transceiver

family complementing NCV734x CAN family and previous generations

of CAN transceivers such as AMIS42665, AMIS3066x, etc.

Due to the wide common−mode voltage range of the receiver inputs

and other design features, the NCV7349 is able to reach outstanding

levels of electromagnetic susceptibility (EMS). Similarly, very low

electromagnetic emission (EME) is achieved by the excellent

matching of the output signals.

Features

•Compatible with the ISO 11898−5 Standard

•High Speed (up to 1 Mbps)

•VIO Pin on NCV7349−3 Version Allowing Direct Interfacing with

3 V to 5 V Microcontrollers

•Very Low Current Standby Mode with Wake−up via the Bus

•Low Electromagnetic Emission (EME) and Extremely High

Electromagnetic Immunity

•Very Low EME without Common−mode (CM) Choke

•No Disturbance of the Bus Lines with an Un−powered Node

•Transmit Data (TxD) Dominant Time−out Function

•Under All Supply Conditions the Chip Behaves Predictably

•Very High ESD Robustness of Bus Pins, >10 kV System ESD Pulses

•Thermal Protection

•Bus Pins Short Circuit Proof to Supply Voltage and Ground

•Bus Pins Protected Against Transients in an Automotive

•These are Pb−Free Devices

Quality

•NCV Prefix for Automotive and Other Applications Requiring

Unique Site and Control Change Requirements; AEC−Q100

Qualified and PPAP Capable

Typical Applications

•Automotive

•Industrial Networks

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NCV7349D10R2G

(Top View)

TxD

RxD

STB

GND

CANL

See detailed ordering and shipping information in the package

dimensions section on page 10 of this data sheet.

ORDERING INFORMATION

VCC

CANH

PIN ASSIGNMENT

MARKING

DIAGRAM

SOIC−8

CASE 751AZ

NV7349−x = Specific Device Code

x = 0 or 3

A = Assembly Location

L = Wafer Lot

Y = Year

W = Work Week

G= Pb−Free Package

NV7349−x

ALYW G

NV7349−0

ALYWG

NCV7349D13R2G

(Top View)

TxD

RxD

STB

GND

CANL

VCC

VIO

CANH

NV7349−3

ALYWG

(Note: Microdot may be in either location)

NCV7349

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Table 1. KEY TECHNICAL CHARACTERISTICS AND OPERATING RANGES

Symbol Parameter Conditions Min Max Unit

VCC Power supply voltage (Note 1) 4.75

(4.5) 5.25

(5.5) V

VUV Undervoltage detection voltage on pin Vcc 2 4 V

VCANH DC voltage at pin CANH 0 < VCC < 5.5 V; no time limit −50 +50 V

VCANL DC voltage at pin CANL 0 < VCC < 5.5 V; no time limit −50 +50 V

VCANH,Lmax DC voltage at pin CANH and CANL during load

dump condition 0 < VCC < 5.5 V, less than one second − +58 V

VESD Electrostatic discharge voltage IEC 61000−4−2 at pins CANH and CANL −15 15 kV

VO(dif)(bus_dom) Differential bus output voltage in dominant state 45 W < RLT < 65 W1.5 3 V

CM−range Input common−mode range for comparator Guaranteed differential receiver thresh-

old and leakage current −35 +35 V

Cload Load capacitance on IC outputs − 15 pF

tpd0 Propagation delay (NCV7349−0 version) See Figure 7 − 245 ns

tpd3 Propagation delay (NCV7349−3 version) See Figure 7 − 250 ns

TJJunction temperature −40 150 °C

Functional operation above the stresses listed in the Recommended Operating Ranges is not implied. Extended exposure to stresses beyond

the Recommended Operating Ranges limits may affect device reliability.

1. In the range of 4.5 V to 4.75 V and from 5.25 V to 5.5 V the chip is fully functional; some parameters may be outside of the specification.

BLOCK DIAGRAM

Figure 1. Block Diagram

Mode &

Wake−up

control

Wake−up

Filter

NCV7349

STB

GND

RxD

COMP

Timer

TxD 1

Driver control

Thermal

shutdown

CANH

CANL

VIO

VIO (*) VCC

*On NCV7349−0 version pin 5 is not connected. VIO supply is provided by VCC.

NCV7349

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TYPICAL APPLICATION

Micro−

controller

VBAT

GND

CANH

CANL

CAN

BUS

5 V − reg

GND

STB

RxD

TxD 1

NCV7349−0

IN OUT

Figure 2. Application Diagram, NCV7349−0

VCC VCC

RLT = 60 W

5 V − reg

Micro−

controller

VBAT

GND

CANH

CANL

CAN

BUS

3 V − reg

GND

STB

RxD

TxD 1

NCV7349−3

IN OUT

Figure 3. Application Diagram, NCV7349−3

VCC

VIO

RLT = 60 W

Table 2. PIN FUNCTION DESCRIPTION

Pin Name Description

1 TxD Transmit data input; low input Ù Driving dominant on bus; internal pull−up current

2 GND Ground

3 VCC Supply voltage

4 RxD Receive data output; bus in dominant Ù low output

5NC

VIO

Not connected. On NCV7349−0 only.

Input / Output pins supply voltage. On NCV7349−3 only

6 CANL Low−level CAN bus line (low in dominant mode)

7 CANH High−level CAN bus line (high in dominant mode)

8 STB Standby mode control input; internal pull−up current

NCV7349

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FUNCTIONAL DESCRIPTION

NCV7349 has two versions which differ from each other

only by function of pin 5.

NCV7349−0: Pin 5 is not connected. (see Figure 2)

NCV7349−3: Pin 5 is VIO pin, which is supply pin for

transceiver digital inputs/output (supplying pins TxD, RxD,

STB) The VIO pin should be connected to microcontroller

supply pin. By using VIO supply pin shared with

microcontroller the I/O levels between microcontroller and

transceiver are properly adjusted. This adjustment allows in

applications with microcontroller supply down to 3 V to

easy communicate with the transceiver. (See Figure 3)

Operating Modes

NCV7349 provides two modes of operation as illustrated

in Table 3. These modes are selectable through pin STB.

Table 3. OPERATING MODES

STB Mode

Pin RxD

Low High

Low Normal Bus dominant Bus recessive

High Standby W ake−up request

detected No wake−up

request detected

Normal Mode

In the normal mode, the transceiver is able to

communicate via the bus lines. The signals are transmitted

and received to the CAN controller via the pins TxD and

RxD. The slopes on the bus lines outputs are optimized to

give low EME.

Standby Mode

In standby mode both the transmitter and receiver are

disabled and a very low−power differential receiver

monitors the bus lines for CAN bus activity. The bus lines

are terminated to ground and supply current is reduced to a

minimum, typically 10 mA. When a wake−up request is

detected by the low−power differential receiver, the signal

is first filtered and then verified as a valid wake signal after

a time period of twake, the RxD pin is driven low by the

transceiver to inform the controller of the wake−up request.

VIO Supply pin

The VIO pin available only on NCV7349−3 version

should be connected to microcontroller supply pin. By using

VIO supply pin shared with microcontroller the I/O levels

between microcontroller and transceiver are properly

adjusted. See Figure 3. Pin VIO on NCV7349−3 does not

provide the internal supply voltage for low−power

differential receiver of the transceiver. Detection of

wake−up request is not possible when there is no supply

voltage on pin VCC.

Wake−up

When a valid wake−up (dominant state longer than twake)

is received during the standby mode the RxD pin is driven

low. The wake−up detection is not latched: RxD returns to

High state after tdwakedr when the bus signal is released back

to recessive – see Figure 4.

Figure 4. NCV7349 Wake−up Behavior

CANH

CANL

STB

RxD1

time

normal standby

>tWake <tWake

tdwakerd tdwakedr

tWake(RxD)

NCV7349

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Over−temperature Detection

A thermal protection circuit protects the IC from damage

by switching off the transmitter if the junction temperature

exceeds a value of approximately 170°C. Because the

transmitter dissipates most of the power, the power

dissipation and temperature of the IC is reduced. All other

IC functions continue to operate. The transmitter off−state

resets when the temperature decreases below the shutdown

threshold and pin TxD goes high. The thermal protection

circuit is particularly needed when a bus line short circuits.

TxD Dominant Time−out Function

A TxD dominant time−out timer circuit prevents the bus

lines being driven to a permanent dominant state (blocking

all network communication) if pin TxD is forced

permanently low by a hardware and/or software application

failure. The timer is triggered by a negative edge on pin TxD.

If the duration of the low−level on pin TxD exceeds the

internal timer value tdom(TxD), the transmitter is disabled,

driving the bus into a recessive state. The timer is reset by a

positive edge on pin TxD.

This TxD dominant time−out time (tdom(TxD)) defines the

minimum possible bit rate to 15 kbps.

Fail Safe Features

A current−limiting circuit protects the transmitter output

stage from damage caused by accidental short circuit to

either positive or negative supply voltage, although power

dissipation increases during this fault condition.

Undervoltage on VCC pin prevents the chip sending data

on the bus when there is not enough VCC supply voltage.

After supply is recovered TxD pin must be first released to

high to allow sending dominant bits again. Recovery time

from undervoltage detection is equal to td(stb−nm) time.

VIO supply dropping below VUVDVIO undervoltage

detection level will cause the transmitter to disengage from

the bus (no bus loading) until the VIO voltage recovers

(NCV7349−3 version only).

The pins CANH and CANL are protected from

automotive electrical transients (according to ISO 7637; see

Figure 7). Pins TxD and STB are pulled high internally

should the input become disconnected. Pins TxD, STB and

RxD will be floating, preventing reverse supply should the

VIO supply be removed.

NCV7349

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ELECTRICAL CHARACTERISTICS

Definitions

All voltages are referenced to GND (pin 2). Positive currents flow into the IC. Sinking current means the current is flowing

into the pin; sourcing current means the current is flowing out of the pin.

ABSOLUTE MAXIMUM RATINGS

Table 4. ABSOLUTE MAXIMUM RATINGS

Symbol Parameter Conditions Min. Max. Unit

VSUP Supply voltage VCC, VIO −0.3 +6 V

VCANH DC voltage at pin CANH 0 < VCC < 5.5 V; no time limit −50 +50 V

VCANL DC voltage at pin CANL 0 < VCC < 5.5 V; no time limit −50 +50 V

VIO DC voltage at pin TxD, RxD, STB −0.3 6 V

Vesd Electrostatic discharge voltage at all pins (Note 2)

(Note 3) −6

500 6

500 kV

Electrostatic discharge voltage at CANH and CANL pins (Note 4) −10 10 kV

Vschaff Transient voltage (Note 5) −150 100 V

Latch−up Static latch−up at all pins (Note 6) 150 mA

Tstg Storage temperature −55 +150 °C

TAAmbient temperature −40 +125 °C

TJMaximum junction temperature −40 +170 °C

Stresses exceeding those listed in the Maximum Ratings table may damage the device. If any of these limits are exceeded, device functionality

should not be assumed, damage may occur and reliability may be af fected.

2. Standardized human body model electrostatic discharge (ESD) pulses in accordance to EIA−JESD22. Equivalent to discharging a 100 pF

capacitor through a 1.5 kW resistor.

3. Standardized charged device model ESD pulses when tested according to ESD−STM5.3.1−1999.

4. System human body model electrostatic discharge (ESD) pulses. Equivalent to discharging a 150 pF capacitor through a 330 W resistor

referenced to GND.

5. Pulses 1, 2a, 3a and 3b according to ISO 7637 part 3. Indicative values based on structural similarity to NCV7340 where results were verified

by external test house.

6. Static latch−up immunity: Static latch−up protection level when tested according to EIA/JESD78.

Table 5. THERMAL CHARACTERISTICS

Symbol Parameter Conditions Value Unit

RqJA_1 Thermal Resistance Junction−to−Air, 1S0P PCB (Note 7) Free air 125 K/W

RqJA_2 Thermal Resistance Junction−to−Air, 2S2P PCB (Note 8) Free air 75 K/W

7. Test board according to EIA/JEDEC Standard JESD51−3, signal layer with 10% trace coverage

8. Test board according to EIA/JEDEC Standard JESD51−7, signal layers with 10% trace coverage

NCV7349

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ELECTRICAL CHARACTERISTICS

Table 6. CHARACTERISTICS (VCC = 4.75 V to 5.25 V; VIO = 2.8 V to 5.5 V (NCV7349−3 only); TJ = −40 to +150°C; RLT = 60 W

unless specified otherwise. On chip versions without VIO pin, reference voltage for all digital inputs and outputs is VCC instead of VIO.)

Symbol Parameter Conditions Min Typ Max Unit

SUPPLY (Pin VCC)

ICC Supply current Dominant; VTxD = 0 V

Recessive; VTxD = VIO − 48

675

10 mA

ICCS Supply current in standby mode TJ ≤ 100°C, (Note 9) − 10 15 mA

VUVDVCC Undervoltage detection voltage on VCC

pin 2 3 4 V

SUPPLY (pin VIO) on NCV7349−3 Version Only

VIO Supply voltage on pin VIO 2.8 − 5.5 V

IIOS Supply current on pin VIO in standby

mode Standby mode − 1 − mA

IIONM Supply current on pin VIO in normal

mode Dominant; VTxD = 0 V

Recessive; VTxD = VIO

For VIO ≤ VCC

− − 1

0.2 mA

VUVDVIO Undervoltage detection voltage on VIO

pin 1.3 − 2.7 V

TRANSMITTER DATA INPUT (Pin TxD)

VIH High−level input voltage Output recessive 2.0 − VIO V

VIL Low−level input voltage Output dominant −0.3 − +0.8 V

IIH High−level input current VTxD = VIO −5 0 +5 mA

IIL Low−level input current VTxD = 0 V −350 −200 −mA

CiInput capacitance (Note 9) − 5 10 pF

TRANSMITTER MODE SELECT (Pin STB)

VIH High−level input voltage Standby mode 2.0 − VIO V

VIL Low−level input voltage Normal mode −0.3 − +0.8 V

IIH High−level input current VSTB = VIO −5 0 +5 mA

IIL0 Low−level input current, NCV7349−0 VSTB = 0 V −10 −4 −1 mA

IIL3 Low−level input current, NCV7349−3 VSTB = 0 V −40 −20 −4 mA

CiInput capacitance (Note 9) − 5 10 pF

RECEIVER DATA OUTPUT (Pin RxD)

IOH High−level output current Normal mode, VRxD = VIO –

0.4 V −1 −0.4 −0.1 mA

IOL Low−level output current VRxD = 0.4 V 1.6 6 12 mA

VOH High−level output voltage,

Weaker RxD pin in Standby mode is on

NCV7349−0 version only

Standby mode, IRxD = −100 mAVCC − 1.1 VCC − 0.7 VCC − 0.4 V

BUS LINES (Pins CANH and CANL)

Vo(reces) (norm) Recessive bus voltage on pins CANH

and CANL VTxD = VIO; no load;

normal mode 2.0 2.5 3.0 V

Vo(reces) (stby) Recessive bus voltage on pins CANH

and CANL VTxD = VIO; no load;

standby mode −100 0 100 mV

Io(reces) (CANH) Recessive output current at pin CANH −35 V < VCANH < +35 V;

0 V < VCC < 5.25 V −2.5 − +2.5 mA

Io(reces) (CANL) Recessive output current at pin CANL −35 V < VCANL < +35 V;

0 V < VCC < 5.25 V −2.5 − +2.5 mA

9. Values based on design and characterization, not tested in production

NCV7349

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Table 6. CHARACTERISTICS (VCC = 4.75 V to 5.25 V; VIO = 2.8 V to 5.5 V (NCV7349−3 only); TJ = −40 to +150°C; RLT = 60 W

unless specified otherwise. On chip versions without VIO pin, reference voltage for all digital inputs and outputs is VCC instead of VIO.)

Symbol UnitMaxTypMinConditionsParameter

BUS LINES (Pins CANH and CANL)

ILI(CANH) Input leakage current to pin CANH 0 W < R(VCC to GND) < 1 MW

VCANL = VCANH = 5 V −10 0 10 mA

ILI(CANL) Input leakage current to pin CANL 0 W < R(VCC to GND) < 1 MW

VCANL = VCANH = 5 V −10 0 10 mA

Vo(dom) (CANH) Dominant output voltage at pin CANH VTxD = 0 V 3.0 3.6 4.25 V

Vo(dom) (CANL) Dominant output voltage at pin CANL VTxD = 0 V 0.5 1.4 1.75 V

Vo(dif) (bus_dom) Differential bus output voltage

(VCANH − VCANL)VTxD = 0 V; dominant;

45 W < RLT < 65 W1.5 2.25 3.0 V

Vo(dif) (bus_rec) Differential bus output voltage

(VCANH − VCANL)VTxD = VIO; recessive; no load −120 0 +50 mV

Io(sc) (CANH) Short circuit output current at pin CANH VCANH = 0 V; VTxD = 0 V −100 −70 −45 mA

Io(sc) (CANL) Short circuit output current at pin CANL VCANL = 36 V; VTxD = 0 V 45 70 100 mA

Vi(dif)R (th) Differential receiver threshold voltage –

Dominant to Recessive (see Figure 6) −2 V < VCANL < +7 V;

−2 V < VCANH < +7 V 0.5 0.6 0.7 V

Vi(dif)D (th) Differential receiver threshold voltage –

Recessive to Dominant (see Figure 6) −2 V < VCANL < +7 V;

−2 V < VCANH < +7 V 0.7 0.8 0.9 V

VihcmR(dif) (th) Differential receiver threshold voltage –

Dominant to Recessive (see Figure 6) −35 V < VCANL < +35 V;

−35 V < VCANH < +35 V 0.4 − 0.8 V

VihcmD(dif) (th) Differential receiver threshold voltage –

Recessive to Dominant (see Figure 6) −35 V < VCANL < +35 V;

−35 V < VCANH < +35 V 0.6 − 1 V

VihcmD12(dif) (th) Differential receiver threshold voltage –

Both transitions (see Figure 6) −12 V < VCANL < +12 V;

−12 V < VCANH < +12 V 0.5 − 0.9 V

Vi(dif) (hys) Differential receiver input voltage hys-

teresis −2 V < VCANL < +7 V;

−2 V < VCANH < +7 V 100 200 300 mV

Vi(dif)

(th)_STDBY Differential receiver threshold voltage

in standby mode −12 V < VCANL < +12 V;

−12 V < VCANH < +12 V 0.4 0.8 1.15 V

Ri(cm) (CANH) Common−mode input resistance at pin

CANH 15 26 37 kW

Ri(cm) (CANL) Common−mode input resistance at pin

CANL 15 26 37 kW

Ri(cm) (m) Matching between pin CANH and pin

CANL common mode input resistance VCANH = VCANL −3 0 +3 %

Ri(dif) Differential input resistance 25 50 75 kW

Ci(CANH) Input capacitance at pin CANH VTxD = VIO; (Note 9) − − 30 pF

Ci(CANL) Input capacitance at pin CANL VTxD = VIO; (Note 9) − − 30 pF

Ci(dif) Differential input capacitance VTxD = VIO; (Note 9) − 3.75 10 pF

THERMAL SHUTDOWN

TJ(sd) Shutdown junction temperature Junction temperature rising 150 170 185 °C

TIMING CHARACTERISTICS (see Figure 5 and Figure 8)

td(TxD−BUSon) Delay TxD to bus active Ci = 100 pF between CANH to

CANL − 50 − ns

td(TxD−BUSoff) Delay TxD to bus inactive Ci = 100 pF between CANH to

CANL − 60 − ns

td(BUSon−RxD) Delay bus active to RxD CRxD = 15 pF − 60 − ns

td(BUSoff−RxD) Delay bus inactive to RxD CRxD = 15 pF − 60 − ns

9. Values based on design and characterization, not tested in production

NCV7349

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Table 6. CHARACTERISTICS (VCC = 4.75 V to 5.25 V; VIO = 2.8 V to 5.5 V (NCV7349−3 only); TJ = −40 to +150°C; RLT = 60 W

unless specified otherwise. On chip versions without VIO pin, reference voltage for all digital inputs and outputs is VCC instead of VIO.)

Symbol UnitMaxTypMinConditionsParameter

TIMING CHARACTERISTICS (see Figure 5 and Figure 8)

tpd Propagation delay TxD to RxD

(NCV7349−0 version) Ci = 100 pF between CANH to

CANL − 125 245 ns

Propagation delay TxD to RxD

(NCV7349−3 version) Ci = 100 pF between CANH to

CANL − 130 250 ns

td(stb−nm) Delay standby mode to normal mode 5 8 20 ms

twake Dominant time for wake−up via bus 0.5 2.5 5 ms

tdwakerd Delay to flag wake event (recessive to

dominant transitions) (See Figure 4) Valid bus wake−up event,

CRxD = 15 pF 1 4.5 10 ms

tdwakedr Delay to flag wake event (dominant to

recessive transitions) (See Figure 4) Valid bus wake−up event,

CRxD = 15 pF 0.5 3.3 7 ms

twake(RxD) Minimum pulse width on RxD

(See Figure 4) 5 ms tWAKE, CRxD = 15 pF 0.5 − − ms

tdom(TxD) TxD dominant time for time−out VTxD = 0 V 1.2 2.6 4 ms

9. Values based on design and characterization, not tested in production

Product parametric performance is indicated in the Electrical Characteristics for the listed test conditions, unless otherwise noted. Product

performance may not be indicated by the Electrical Characteristics if operated under different conditions.

MEASUREMENT SETUPS AND DEFINITIONS

dominant

0.9 V

0.5 V

recessive

50%

recessive

50%

TxD

CANH

CANL

RxD

Figure 5. Transceiver Timing Diagram

tpd

0.7 x VCC (*)

td(BUSoff−RXD)

0.3 x VCC (*)

tpd

td(BUSon−RXD)

td(TxD−BUSoff)

td(TxD−BUSon)

Vi(dif) =

VCANH − VCANL

*On NCV7349−3 VCC is replaced by VIO

NCV7349

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High

Low

0.5 0.9

Hysteresis

Figure 6. Hysteresis of the Receiver

VRxD

Vi(dif)(hys)

NCV7349

GND

3CANH

CANL

STB

RxD 4

TxD 1

100 nF

+5 V

15 pF

1 nF

Transient

Generator

Figure 7. Test Circuit for Automotive Transients

VCC

NCV7349

GND

3CANH

CANL

STB

RxD 4

TxD 1

100 pF

100 nF

+5 V

15 pF

Figure 8. Test Circuit for Timing Characteristics

VCC

CLT

RLT

60 W

DEVICE ORDERING INFORMATION

Part Number Description Temperature

Range Package Shipping †

NCV7349D10R2G High Speed Low Power CAN Transceiver

for the Japanese Market −40°C to +125°CSOIC 150 8 GREEN

(Matte Sn, JEDEC

MS−012)

(Pb−Free)

3000 / Tape &

Reel

NCV7349D13R2G High Speed Low Power CAN Transceiver

for the Japanese Market with VIO pin

†For information on tape and reel specifications, including part orientation and tape sizes, please refer to our Tape and Reel Packaging

Specifications Brochure, BRD8011/D.

NCV7349

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PACKAGE DIMENSIONS

SOIC 8

CASE 751AZ

ISSUE A

NCV7349

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Phone: 421 33 790 2910

Japan Customer Focus Center

Phone: 81−3−5817−1050

NCV7349/D

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