ISL33334EIAZ-T_技术文档

DATASHEET

ISL33334E, ISL33337E

3.3V, ±15kV ESD Protected, Two Port, Dual Protocol (RS-232/RS-485)

Transceivers

FN8776

Rev 1.00

October 21, 2016

The ISL33334E, ISL33337E are two port interface ICs where

Features

port 1 is configured as a dual (2 Tx, 2 Rx) RS-232 transceiver

and port 2 is a single RS-485/RS-422 transceiver.

• ±15kV (HBM) ESD protected bus pins (RS-232 or RS-485)

• Operates from a single 3.3V supply

The on-board charge pump generates RS-232 compliant ±5V

Tx output levels from a single V supply as low as 3.15V. The

transceivers are RS-232 compliant, with the Rx inputs

handling up to ±25V.

• Two independent ports, port 1 set for RS-232 (2 Transceivers)

and port 2 for RS-485/RS-422 (1 transceiver)

CC

• True flow-through pinouts (Rx inputs and Tx outputs all on

the same side) simplify board layouts

The port 2 transceiver supports both the RS-485 and RS-422

differential communication standards. The receiver features

“full fail-safe” operation, so the Rx output remains in a high

state if the inputs are open or shorted together. The

• Pb-free (RoHS compliant)

• Full fail-safe (open/short) RS-485/422 Port 2 Rx

• User selectable RS-485 data rates

transmitter supports two data rates, one of which is slew rate

limited for problem free communication at low data rates. The

active low Rx enable pin (RE485) allows Tx/Rx direction

control, via a single signal, simply by connecting the

corresponding DE485 and RE485 pins together.

- Fast speed. . . . . . . . . . . . . . . . . . . . . . . . . . . . up to 20Mbps

- Slew rate limited . . . . . . . . . . . . . . . . . . . . . . up to 115kbps

• Fast RS-232 data rate . . . . . . . . . . . . . . . . . . . . up to 400kbps

• Small charge pump capacitors . . . . . . . . . . . . . . . . 4 x 0.1µF

• Low current shutdown mode . . . . . . . . . . . . . . . . . . . . . . 40µA

• QFN package saves board space (ISL33337E only)

The ISL33334E and ISL33337E also include a shutdown

function, which disables the Tx and Rx outputs, disables the

charge pumps and places the IC in a low current (40µA) mode.

The ISL33337E is a QFN packaged device for space

constrained applications.

Applications

• Gaming applications (e.g., slot machines)

Related Literature

• For a full list of related documents, visit our website

- ISL33334E, ISL33337E product pages

• Single board computers

• Factory automation

• Security networks

• Industrial/process control networks

• Level translators (e.g., RS-232 to RS-422)

• Point-of-sale equipment

TABLE 1. SUMMARY OF FEATURES

PORT 2

PORT 1

LOW POWER

SHUTDOWN?

PORT 2

RS-485 Rx AND Tx ENABLE?

PART NUMBER

PACKAGE OPTION

RS-485 DATA RATE (bps) RS-232 DATA RATE (bps)

ISL33334E

ISL33337E

28 Ld SSOP

20M, 115k

400k

YES

40 Ld QFN (6x6mm)

FN8776 Rev 1.00

October 21, 2016

Page 1 of 23

ISL33334E, ISL33337E

Ordering Information

PART NUMBER

(Notes 2, 3)

TEMP. RANGE

(°C)

TAPE AND REEL

(UNITS)

PACKAGE

(RoHS COMPLIANT)

PKG.

DWG. #

PART MARKING

ISL33334EIAZ

33334E IAZ

33337E IRZ

-40 to +85

-

1k

-

28 Ld SSOP

M28.209

ISL33334EIAZ-T (Notes 1)

ISL33337EIRZ

28 Ld SSOP

40 Ld QFN

M28.209

L40.6x6

ISL33337EIRZ-T (Notes 1)

1k

250

ISL33337EIRZ-T7A (Notes 1) 33337E IRZ

NOTES:

1. Refer to TB347 for details on reel specifications.

2. These Intersil Pb-free plastic packaged products employ special Pb-free material sets, molding compounds/die attach materials and 100% matte tin

plate plus anneal (e3 termination finish, which is RoHS compliant and compatible with both SnPb and Pb-free soldering operations). Intersil

Pb-free products are MSL classified at Pb-free peak reflow temperatures that meet or exceed the Pb-free requirements of IPC/JEDEC J STD-020.

3. For Moisture Sensitivity Level (MSL), see product information page for ISL33334E, ISL33337E. For more information on MSL, see tech brief TB363.

TABLE 2. KEY DIFFERENCES BETWEEN FAMILY OF PARTS

VCC

(V)

RS485 (bps)

DATA RATE

RS232 (bps)

DATA RATE

PART NUMBER

ISL33354E

ISL33357E

ISL33334E

ISL33337E

PKG

5

28Ld SSOP

40Ld QFN

28Ld SSOP

40Ld QFN

20M, 115k

650k

400k

5

3.3

NOTE: For a full list of dual protocol transceivers, please visit our website.

Pin Configurations

ISL33334E

(28 LD SSOP)

TOP VIEW

ISL33337E

(40 LD QFN)

TOP VIEW

C1+

C1-

1

2

3

4

5

6

7

8

9

28 C2+

27 C2-

40 39 38 37 36 35 34 33 32 31

PORT 1

V+

26 V

CC

PORT 1

R

V+

R1IN

R2OUT

1

2

30

29

28

27

26

25

24

23

22

21

R

25 R2OUT

24 R1OUT

23 T2IN

R1IN

R2IN

T1OUT

T2OUT

*GND

R1OUT

T2IN

R

R2IN

D

3

D

22 T1IN

T1OUT

4

T1IN

21 SHDN

D

T2OUT

*GND

5

*V

CC

*V

20

DI

CC

6

SHDN

DI

Y 10

Z 11

19 DE485

18 RO

D

R

PORT 2

D

7

*V

CC

A 12

17 V-

8

DE485

Y

Z

B 13

16 RE485

15 GND

9

RO

SLOW485 14

PORT 2

R

EP

DNC

10

A

* NOT A SUPPLY PIN, BUT MUST BE CONNECTED TO THE

NOTED SUPPLY.

11 12 13 14 15 16 17 18 19 20

FN8776 Rev 1.00

October 21, 2016

Page 2 of 23

ISL33334E, ISL33337E

Pin Descriptions

PIN#for PIN # for

PORT/

MODE

PIN NAME SSOP

QFN

FUNCTION

NC

-

32, 33, 39, BOTH

40

No Internal Connection.

DNC

-

21

25

BOTH

Do not make any external connections to this pin.

SHDN

21

A low on SHDN disables the charge pumps, disables all the outputs and places the device in low power

shutdown. Internally pulled-high. SHDN = 1 for normal operation.

V

26

15

31, 34 BOTH

15, 16 BOTH

System power supply input (3.15V to 3.45V). Both pins 31 and 34 must connect to the V supply.

CC

GND

Ground connection. QFN pins 15 and 16 must both connect to GND. This is also the potential of the QFN’s

exposed metal pad (EP).

*V

CC

9

12, 20, 7, BOTH

14, 26

For proper operation, connect this lead to the V supply. This is not a power supply lead, so no decoupling

CC

is required.

*GND

RxIN

8

6, 17

2, 3

BOTH

For proper operation, connect this lead to GND. This is not a power supply lead.

4, 5

1 / RS-232 RS-232 receiver input with ±15kV ESD protection. A low on RxIN forces RxOUT high; a high on RXIN forces

RxOUT low.

RxOUT

TxIN

24, 25

22, 23

29, 30 1 / RS-232 RS-232 receiver output.

27, 28

1 / RS-232 RS-232 transmitter input. A low on TxIN drives the corresponding TxOUT high, while a high on TxIN drives

the corresponding TxOUT low.

TxOUT

C1+

C1-

C2+

C2-

V+

V-

6, 7

1

4, 5

37

38

36

35

1

1 / RS-232 RS-232 transmitter output with ±15kV ESD protection.

1 / RS-232 External charge pump capacitor is connected to this lead.

1 / RS-232 Internally generated positive RS-232 transmitter supply (+5.5V).

1 / RS-232 Internally generated negative RS-232 transmitter supply (-5.5V).

2 / RS-485 RS-485 noninverting receiver input with ±15kV ESD protection.

2 / RS-485 RS-485 inverting receiver input with ±15kV ESD protection.

2/ RS-485 RS-485 noninverting driver output with ±15kV ESD protection.

2/ RS-485 RS-485 inverting driver output with ±15kV ESD protection.

2 / RS-485 RS-485 driver input. A low on DI forces output Y low and output Z high.

2

28

27

3

17

12

13

10

11

20

18

19

10

11

8

A

B

Y

Z

9

DI

24

22

RO

2 / RS-485 RS-485 receiver output: If A > B by at least -40mV, RO is high; If A < B by -200mV or more, RO is low;

RO = High if A and B are unconnected (floating) or shorted together (i.e., full fail-safe).

SLOW485

RE485

DE485

EP

14

16

19

-

13

18

23

EP

2 / RS-485 RS-485 data rate control. A low on SLOW485 selects the 115kbps RS-485 data rate (slew rate limited

output transitions); a high selects the 20Mbps data rate (full speed transitions). Internally pulled-high.

2/ RS-485 RS-485 active low receiver output enable. RO is enabled when RE485 is low; RO is high impedance when

RE485 is high. Internally pulled low.

2/ RS-485 RS-485 driver output enable (DE). The driver outputs, Y and Z, are enabled by driving DE485 high. They

are high impedance when DE485 is low. Internally pulled high.

BOTH

QFN exposed thermal pad (EPAD). Connect to GND.

TABLE 3. ISL33334E AND ISL33337E FUNCTION TABLE

INPUTS

RECEIVER OUTPUTS

DRIVER OUTPUTS

DRIVER

DATA

RATE

R1OUT

AND

CHARGE

PUMPS

(Note 4)

T1OUT AND

PORT

1

SHDN

1

RE485

N.A.

DE485 SLOW485

N.A. N.A.

RO

R2OUT

Y AND Z

N.A.

T2OUT

(bps)

MODE

N.A.

ON

400k

RS-232

FN8776 Rev 1.00

October 21, 2016

Page 3 of 23

ISL33334E, ISL33337E

TABLE 3. ISL33334E AND ISL33337E FUNCTION TABLE

INPUTS

RECEIVER OUTPUTS

DRIVER OUTPUTS

DRIVER

DATA

RATE

R1OUT

AND

CHARGE

PUMPS

(Note 4)

T1OUT AND

PORT

SHDN

RE485

DE485 SLOW485

RO

ON

R2OUT

Y AND Z

High-Z

ON

T2OUT

(bps)

MODE

2

1

0

1

0

N.A.

ON

115k

RS-485 Rx

N.A.

RS-485 Tx

and Rx

2

1

0

1

0

1

0

1

High-Z

ON

N.A.

ON

High-Z

ON

N.A.

ON

115k

20M

RS-485 Tx

RS-485 Rx

ON

RS-485 Tx

and Rx

2

1

0

1

X

1

X

1

X

High-Z

N.A.

ON

N.A.

ON

20M

N.A.

RS-485 Tx

Shutdown

1 AND 2

High-Z

OFF

NOTE:

4. Charge pumps are off if SHDN = 0. If SHDN = 1, the charge pumps are on.

Truth Tables

RS-485 TRANSMITTING (PORT 2)

INPUTS OUTPUTS

RS-232 TRANSMITTING (PORT 1)

INPUTS

OUTPUTS

DATA RATE

(bps)

SHDN

T1IN

0

T2IN

0

T1OUT

T2OUT

SHDN DE485

DI

0

1

0

1

X

SLOW485

Y

0

1

0

1

Z

1

0

1

0

1

0

1

0

1

0

X

0

1

X

115k

20M

N.A.

0

1

0

1

0

1

0

X

High-Z

High-Z High-Z

X

N.A.

RS-232 RECEIVING (PORT 1)

INPUTS

OUTPUTS

RS-485 RECEIVING (PORT 2)

INPUTS

SHDN

R1IN

R2IN

R1OUT

R2OUT

OUTPUT

1

0

1

SHDN

RE485

A-B

RO

1

0

1

0

1

X

≥-40mV

1

0

1

0

≤-200mV

0

1

Open or Shorted together

1

Open

X

Open

X

1

X

High-Z

FN8776 Rev 1.00

October 21, 2016

Page 4 of 23

ISL33334E, ISL33337E

Typical Operating Circuits

+3.3V

+

0.1µF

9, 26

1

C

1

0.1µF

C1+

V

3

CC

+

C

3

0.1µF

+

V+

V-

2

C1-

28

C

2

C2+

+

17

0.1µF

C

4

27

C2-

0.1µF

+

4

24

25

R1OUT

R2OUT

R1IN

R2IN

R

5k?

5

R

5k?

7

6

23

22

D

T2OUT

T1OUT

T2IN

T1IN

13

12

B

A

18

16

R

RO

RE485

11

10

Z

Y

20

DI

D

19

DE485

V

CC

21

V

CC

SHDN

14

SLOW485

GND

8, 15

NOTE: PINOUT FOR SSOP

FIGURE 1. PORT RS-232 MODE AND 1 PORT RS-485 MODE

FN8776 Rev 1.00

October 21, 2016

Page 5 of 23

ISL33334E, ISL33337E

Absolute Maximum Ratings (T = +25°C)

Thermal Information

A

V

to Ground . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 7V

Thermal Resistance (Typical)

28 Ld SSOP Package (Notes 7, 9). . . . . . . .

40 Ld QFN Package (Notes 6, 8) . . . . . . . . .

Maximum Junction Temperature (Plastic Package) . . . . . . . . . . . . +150°C

Maximum Storage Temperature Range . . . . . . . . . . . . . . -65°C to +150°C

Pb-free Reflow Profile . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .see TB493

_JA(°C/W) _JC(°C/W)

CC

Input Voltages

60

36

All Except A,B, RxIN. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . -0.5V to 7V

Input/Output Voltages

32

2.5

A, B, RxIN . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . -25V to +25V

Y, Z, TxOUT (Note 5). . . . . . . . . . . . . . . . . . . . . . . . . . . . . -12.5V to +12.5V

RO, RxOUT . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . -0.5V to (V + 0.5V)

CC

Output Short-circuit Duration

Recommended Operating Conditions

Y, Z, TxOUT, RxOUT. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Indefinite

ESD Rating . . . . . . . . . . . . . . . . . . . . . . . See Specification Table on page 7

Latch-up (per JESD78D, Level 2, Class A) . . . . . . . . . . . . . . . . . . . . . +85°C

Supply Voltage (V ) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3.3V

CC

Temperature Range. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . -40°C to +85°C

RS-485 Tx Load . . . . . . . . . . . . . . . . . . . . . . One or two 120Ω Terminations

CAUTION: Do not operate at or near the maximum ratings listed for extended periods of time. Exposure to such conditions may adversely impact product

reliability and result in failures not covered by warranty.

NOTES:

5. One output at a time, I

OUT

≤100mA for ≤10 mins.

6.  is measured in free air with the component mounted on a high effective thermal conductivity test board with “direct attach” features. See Tech

JA

Brief TB379.

7.  is measured with the component mounted on a high effective thermal conductivity test board in free air. See Tech Brief TB379 for details.

JA

8. For  , the “case temp” location is the center of the exposed metal pad on the package underside.

JC

9. For  , the “case temp” location is taken at the package top center.

JC

Electrical Specifications Test Conditions: V = 3.15V to 3.45V, C - C = 0.1µF; unless otherwise specified. Typicals are at V = 3.3V,

CC

1

4

CC

T

= +25°C (Note 10). Boldface limits apply across the operating temperature range, -40°C to +85°C.

A

TEMP

(°C) (Note 14)

MIN

MAX

(Note 14) UNIT

PARAMETER

SYMBOL

TEST CONDITIONS

TYP

DC CHARACTERISTICS - RS-485 DRIVER (PORT 2)

Driver Differential V

(no load)

V

Full

-

2

-

2.3

2

V

OUT

OD1

CC

(with load)

R = 50Ω (RS-422) (Figure 2)

R = 27Ω (RS-485) (Figure 2)

-

OUT

OD2

1.5

-

5

V

R

= 60Ω, R = 375Ω, V = -7V to 12V (Figure 2) Full

D CM

-

OD3

Change in Magnitude of Driver

Differential V for

V

R = 27Ω or 50Ω (Figure 2)

Full

0.01

0.2

OD

OUT

Complementary Output States

Driver Common-Mode V

OUT

V

R = 27Ω or 50Ω (Figure 2)

Full

-

3

V

OC

Change in Magnitude of Driver

Common-Mode V for

V

OC

0.01

0.2

OUT

Complementary Output States

Driver Short-Circuit Current,

I

-7V ≤ (V or V ) ≤ 12V (Note 12)

Full

35

-

250

mA

OS

Y

Z

V

= High or Low

OUT

Driver Three-State Output Leakage

Current (Y, Z)

I

Outputs disabled,

= 0V or 3.6V

V

= 12V

= -7V

Full

-

200

-

µA

OZ

OUT

V

CC

-200

OUT

DC CHARACTERISTICS - RS-232 DRIVER (PORT 1)

Driver Output Voltage Swing

V

All T

loaded with 3kΩ to ground

= 0V

OUT

Full

±5

-

V

O

OUTS

Driver Output Short-Circuit Current

I

V

-60

60

mA

OS

DC CHARACTERISTICS - LOGIC PINS (i.e., DRIVER AND CONTROL INPUT PINS)

Input High Voltage

Input Low Voltage

Input Current

V

Full

2.2

-

V

IH

V

0.8

2

IL

I

Pins Without Pull ups or Pull downs

SLOW485, DE485, RE485, SHDN

-2

µA

IN1

I

-25

25

IN2

FN8776 Rev 1.00

October 21, 2016

Page 6 of 23

ISL33334E, ISL33337E

Electrical Specifications Test Conditions: V = 3.15V to 3.45V, C - C = 0.1µF; unless otherwise specified. Typicals are at V = 3.3V,

CC

1

4

CC

T

= +25°C (Note 10). (Continued)Boldface limits apply across the operating temperature range, -40°C to +85°C. (Continued)

A

TEMP

(°C) (Note 14)

MIN

MAX

(Note 14) UNIT

PARAMETER

SYMBOL

TEST CONDITIONS

TYP

-

DC CHARACTERISTICS - RS-485 RECEIVER INPUTS (PORT 2)

Receiver Differential Threshold

Voltage

V

-7V ≤ V ≤ 12V, full fail-safe

CM

Full

-0.2

-0.04

V

TH

Receiver Input Hysteresis

V

V

= 0V

25

Full

-

35

-

mV

mA

kΩ

TH

CM

Receiver Input Current (A, B)

I

= 0V or 3.0 to 3.6V

V

= 12V

= -7V

-

0.8

IN

CC

IN

-0.64

15

-

Receiver Input Resistance

R

-7V ≤ V ≤ 12V, V = 0 (Note 13) or

CM CC

IN

3V ≤ V ≤ 3.6V

CC

DC CHARACTERISTICS - RS-232 RECEIVER INPUTS (PORT 1)

Receiver Input Voltage Range

Receiver Input Threshold

VIN

Full

25

-25

-

25

0.8

-

V

-

2.4

-

1.1

1.6

0.5

5

IL

V

IH

Receiver Input Hysteresis

Receiver Input Resistance

V

-

V

TH

IN

R

V

= ±15V, V powered up (Note 13)

CC

Full

3

7

kΩ

IN

DC CHARACTERISTICS - RECEIVER OUTPUTS (PORT 1 and 2)

Receiver Output High Voltage

Receiver Output Low Voltage

Receiver Short-Circuit Current

Receiver Three-State Output Current

POWER SUPPLY CHARACTERISTICS

No-Load Supply Current, (Note 11)

Shutdown Supply Current

V

I

= -1.5mA

= 5mA

Full

V

-0.4

-

V

OH

O

CC

V

-

0.2

0.4

85

OL

I

0V ≤ V ≤ V

CC

7

-

mA

µA

OSR

O

I

Output Disabled, 0V ≤ V ≤ V

CC

-

±10

OZR

O

I

SHDN = V

CC

Full

-

3.7

40

7

mA

µA

CC

I

SHDN = SLOW485 = GND, RE485 = V

,

CC

160

SHDN

DE485 = GND

ESD CHARACTERISTICS

Bus Pins (A, B, Y, Z, RxIN, TxOUT) Any

Port

Human body model

25

-

±15

-

kV

All Other Pins

Human body model

Machine model

25

-

±2.5

-

kV

V

±200

RS-232 DRIVER AND RECEIVER SWITCHING CHARACTERISTICS (PORT 1, ALL VERSIONS AND SPEEDS)

Driver Output Transition Region

Slew Rate

SR

R

= 3kΩ, Measured From

C ≥15pF

Full

25

-

20

9

30

V/µs

µs

L

3V to -3V or -3V to 3V

C 2500pF

4

-

3.1

2

L

Driver Output Transition Time

Driver Propagation Delay

t , t

R

= 3kΩ, C = 2500pF, 10% - 90%

0.22

1.2

1

r

f

L

t

= 3kΩ C = 1000pF (Figure 7)

-

µs

DPHL

L

t

-

1.2

300

25

400

2

µs

DPLH

Driver Propagation Delay Skew

Driver Enable Time from Shutdown

Driver Maximum Data Rate

t

- t

(Figure 7)

= ±3.0V, C = 1000pF

-

450

-

ns

DSKEW

DPHL DPLH

t

V

µs

DENSD

DR

OUT

L

R

= 3kΩ, C = 500pF, One Transmitter

Full

250

-

kbps

D

L

Switching

Receiver Propagation Delay

t

C = 15pF (Figure 8)

Full

-

40

58

120

ns

RPHL

RPLH

L

t

FN8776 Rev 1.00

October 21, 2016

Page 7 of 23

ISL33334E, ISL33337E

Electrical Specifications Test Conditions: V = 3.15V to 3.45V, C - C = 0.1µF; unless otherwise specified. Typicals are at V = 3.3V,

CC

1

4

CC

T

= +25°C (Note 10). (Continued)Boldface limits apply across the operating temperature range, -40°C to +85°C. (Continued)

A

TEMP

(°C) (Note 14)

MIN

MAX

(Note 14) UNIT

PARAMETER

SYMBOL

TEST CONDITIONS

TYP

18

2

Receiver Propagation Delay Skew

Receiver Maximum Data Rate

t

- t

RPHL RPLH

(Figure 8)

Full

-

40

-

ns

RSKEW

DR

C = 15pF

0.46

Mbps

R

L

RS-485 DRIVER SWITCHING CHARACTERISTICS (FAST DATA RATE (20Mbps), PORT 2, (SLOW485 = V ))

CC

Driver Differential Input to Output

Delay

t

, t

DLH DHL

R

= 54Ω, C = 100pF (Figure 3)

Full

10

20

35

ns

DIFF

L

Driver Output Skew

t

R

= 54Ω, C = 100pF (Figure 3)

Full

-

3

-

2

20

28

35

30

100

10

30

ns

SKEW

DIFF

L

Driver Differential Rise or Fall Time

Driver Enable to Output Low

Driver Enable to Output High

Driver Disable from Output Low

Driver Disable from Output High

t , t

= 54Ω, C = 100pF, (Figure 3)

L

R

F

t

C

= 100pF, SW = V (Figure 4)

CC

60

ZL

L

t

= 100pF, SW = GND (Figure 4)

-

60

ZH

t

= 15pF, SW = V (Figure 4)

CC

-

60

LZ

t

= 15pF, SW = GND Figure 4)

-

60

HZ

Driver Enable from Shutdown to

Output Low

t

R

= 500Ω, C = 100pF, SW = V (Figure 4)

CC

-

250

ZL(SHDN)

L

Driver Enable from Shutdown to

Output High

t

= 500Ω, C = 100pF, SW = GND (Figure 4)

Full

-

290

35

375

ns

ZH(SHDN)

L

Driver Maximum Data Rate

f

= 54Ω, C = 100pF (Figure 3)

20

-

Mbps

MAX

DIFF

L

RS-485 DRIVER SWITCHING CHARACTERISTICS (SLOW DATA RATE (115kbps), PORT 2, (SLOW485 = GND))

Driver Differential Input to Output

Delay

t

, t

DLH DHL

R

= 54Ω, C = 100pF (Figure 3)

Full

800

1600

2500

ns

DIFF

L

Driver Output Skew

t

R

= 54Ω, C = 100pF (Figure 3)

Full

-

250

1700

45

500

3100

100

1200

60

ns

SKEW

DIFF

L

Driver Differential Rise or Fall Time

Driver Enable to Output Low

Driver Enable to Output High

Driver Disable from Output Low

Driver Disable from Output High

t , t

= 54Ω, C = 100pF (Figure 3)

1000

R

F

L

t

C

= 100pF, SW = V (Figure 4)

CC

-

ZL

L

t

= 100pF, SW = GND (Figure 4)

900

35

ZH

t

= 15pF, SW = V (Figure 4)

CC

LZ

t

= 15pF, SW = GND (Figure 4)

25

60

HZ

Driver Enable from Shutdown to

Output Low

t

R

= 500Ω, C = 100pF, SW = V (Figure 4)

CC

-

800

ZL(SHDN)

L

Driver Enable from Shutdown to

Output High

t

= 500Ω, C = 100pF, SW = GND (Figure 4)

Full

-

1500

ns

ZH(SHDN)

L

Driver Maximum Data Rate

f

= 54Ω, C = 100pF (Figure 3)

115

800

-

kbps

MAX

DIFF

L

RS-485 RECEIVER SWITCHING CHARACTERISTICS (PORT 2, ALL SPEEDS)

Receiver Input to Output Delay

Receiver Skew | t - t

t

, t

PLH PHL

(Figure 5)

Full

20

45

3

70

10

-

ns

|

t

-

PLH PHL

SKEW

Receiver Maximum Data Rate

Receiver Enable to Output Low

Receiver Enable to Output High

Receiver Disable from Output Low

Receiver Disable from Output High

f

20

40

20

500

Mbps

ns

MAX

t

C

= 15pF, SW = V (Figure 6)

CC

-

60

900

ZL

L

t

= 15pF, SW = GND (Figure 6)

ns

ZH

t

= 15pF, SW = V (Figure 6)

CC

ns

LZ

t

= 15pF, SW = GND (Figure 6)

ns

HZ

Receiver Enable from Shutdown to

Output Low

t

= 15pF, SW = V (Figure 6)

CC

ns

ZLSHDN

Receiver Enable from Shutdown to

Output High

t

C

= 15pF, SW = GND (Figure 6)

Full

-

500

900

ns

ZHSHDN

L

FN8776 Rev 1.00

October 21, 2016

Page 8 of 23

ISL33334E, ISL33337E

Electrical Specifications Test Conditions: V = 3.15V to 3.45V, C - C = 0.1µF; unless otherwise specified. Typicals are at V = 3.3V,

CC

1

4

CC

T

= +25°C (Note 10). (Continued)Boldface limits apply across the operating temperature range, -40°C to +85°C. (Continued)

A

TEMP

(°C) (Note 14)

MIN

MAX

(Note 14) UNIT

PARAMETER

SYMBOL

TEST CONDITIONS

TYP

NOTES:

10. All currents into device pins are positive; all currents out of device pins are negative. All voltages are referenced to device ground unless otherwise

specified.

11. Supply current specification is valid for loaded RS-485 (port 2) drivers when DE485 = 0V.

12. Applies to peak current. See “Typical Performance Curves on page 12” for more information.

13. A, B, RxIN defaults to RS-485 mode (>15kΩ) when the device is unpowered (V = 0V), or in SHDN.

CC

14. Compliance to datasheet limits is assured by one or more methods: production test, characterization and/or design.

Test Circuits and Waveforms

R

DE485

V

CC

Z

Y

DI

R

V

OD

D

V

R

OC

FIGURE 2. RS-485 DRIVER V AND V TEST CIRCUIT

OD OC

3V

DI

50%

PLH

50%

PHL

0V

t

V

OH

50%

OUT (Y)

V

OL

t

PHL

PLH

C

= 100pF

L

V

OH

DE485

DI

V

OUT (Z)

CC

Z

Y

V

OL

R

DIFF

D

t

DLH

90%

DHL

C

L

+V

OD

90%

10%

t

DIFF OUT (Y - Z)

SIGNAL

GENERATOR

0V

10%

-V

OD

t

R

F

SKEW = |t

PLH

(Y or Z) - t

(Z or Y)|

PHL

FIGURE 3B. MEASUREMENT POINTS

FIGURE 3. RS-485 DRIVER PROPAGATION DELAY AND DIFFERENTIAL TRANSITION TIMES

FIGURE 3A. TEST CIRCUIT

FN8776 Rev 1.00

October 21, 2016

Page 9 of 23

ISL33334E, ISL33337E

Test Circuits and Waveforms(Continued)

DE485

ENABLED

50%

Z

Y

500?

V

DI

3V

CC

DE485

(SHDN FOR SHDN)

D

50%

GND

SW

SIGNAL

GENERATOR

0V

C

L

t

ZH

ZH(SHDN)

t

HZ

t

OUTPUT HIGH

2.3V

V

OH

V

- 0.5V

OH

FOR SHDN TESTS, SWITCH SHDN RATHER THAN DE485

OUT (Y, Z)

0V

PARAMETER SHDN/DE485 OUTPUT

DI

SW

C

(pF)

L

t

1/-

-/1

Y/Z

1/0

0/1

1/0

0/1

1/0

0/1

GND

15

t

HZ

ZL

LZ

t

ZL(SHDN)

t

V

15

V

LZ

CC

GND

100

OUT (Y, Z)

ZH

2.3V

V

+ 0.5V

V

OL

t

V

OL

ZL

CC

OUTPUT LOW

t

GND

ZH(SHDN)

t

V

CC

ZL(SHDN)

FIGURE 4A. TEST CIRCUIT

FIGURE 4B. MEASUREMENT POINTS

FIGURE 4. RS-485 DRIVER ENABLE AND DISABLE TIMES

RE485

+1.5V

15pF

A

B

A

0V

RO

R

-1.5V

t

PLH

t

PHL

V

CC

SIGNAL

GENERATOR

RO

1.5V

0V

FIGURE 5B. MEASUREMENT POINTS

FIGURE 5A. TEST CIRCUIT

FIGURE 5. RS-485 RECEIVER PROPAGATION DELAY

RE485

B

1k?

V

3V

RO

CC

R

SHDN

1.5V

ENABLED

1.5V

GND

(FOR SHDN TESTS)

SW

SIGNAL

A

0V

GENERATOR

15pF

3V

RE485

1.5V

HZ

FOR SHDN TESTS, SWITCH SHDN RATHER THAN RE485

0V

t

ZH

t

PARAMETER

SHDN/RE485

A

SW

GND

t

ZH(SHDN)

OUTPUT HIGH

V

t

1/-

-/0

+1.5V

-1.5V

+1.5V

-1.5V

+1.5V

-1.5V

OH

V

- 0.5V

HZ

OH

RO

1.5V

t

V

CC

GND

LZ

0V

t

ZH

t

V

t

ZL

CC

LZ

t

ZL(SHDN)

t

GND

V

ZH(SHDN)

CC

RO

t

V

1.5V

ZL(SHDN)

CC

V

+ 0.5V

OL

V

OL

OUTPUT LOW

FIGURE 6B. MEASUREMENT POINTS

FIGURE 6. RS-485 RECEIVER ENABLE AND DISABLE TIMES

FIGURE 6A. TEST CIRCUIT

FN8776 Rev 1.00

October 21, 2016

Page 10 of 23

ISL33334E, ISL33337E

Test Circuits and Waveforms(Continued)

3V

SHDN

TxIN

V

1.5V

CC

C

L

0V

TxOUT

TxIN

D

t

DPHL

DPLH

V

R

O+

L

SIGNAL

GENERATOR

TxOUT

0V

V

O-

SKEW = |t |

- t

DPHL DPLH

FIGURE 7B. MEASUREMENT POINTS

FIGURE 7A. TEST CIRCUIT

FIGURE 7. RS-232 DRIVER PROPAGATION DELAY AND TRANSITION TIMES

3V

SHDN

V

RxIN

50%

CC

50%

C

= 15pF

L

0V

t

RxOUT

RxIN

R

t

RPLH

RPHL

V

OH

SIGNAL

GENERATOR

RxOUT

50%

V

OL

SKEW = |t

- t |

RPHL RPLH

FIGURE 8B. MEASUREMENT POINTS

FIGURE 8. RS-232 RECEIVER PROPAGATION DELAY AND TRANSITION TIMES

FIGURE 8A. TEST CIRCUIT

FN8776 Rev 1.00

October 21, 2016

Page 11 of 23

ISL33334E, ISL33337E

Typical Performance Curves

V

= 3.3V, T = +25°C, unless otherwise specified

A

CC

30

90

80

70

60

50

40

30

20

10

0

V

, +25 °C

OL

V

, +25 °C

25

20

15

10

5.0

0

OH

V

, +85 °C

OL

V

, +85 °C

OH

0

1

2

3

3.3

0

0.5

1

1.5

2

2.5

3

3.5

RECEIVER OUTPUT VOLTAGE (V)

DIFFERENTIAL OUTPUT VOLTAGE (V)

FIGURE 9. RECEIVER OUTPUT CURRENT vs RECEIVER OUTPUT

VOLTAGE

FIGURE 10. RS-485, DRIVER OUTPUT CURRENT vs DIFFERENTIAL

OUTPUT VOLTAGE

2.30

250

+25 °C

+85 °C

2.25

2.20

2.15

2.10

2.05

2.00

1.95

1.90

R

= 100Ω

200

DIFF

150

-40 °C

100

50

Y OR Z = LOW

0

Y OR Z = HIGH

R

= 54Ω

DIFF

50

-50

-100

-150

+25 °C

+85 °C

-40 °C

-4

-7 -6

-2

0

2

4

6

8

10

12

-40

-25

0

25

75 85

OUTPUT VOLTAGE (V)

TEMPERATURE (°C)

FIGURE 11. RS-485, DRIVER DIFFERENTIAL OUTPUT VOLTAGE vs

TEMPERATURE

FIGURE 12. RS-485, DRIVER OUTPUT CURRENT vs

SHORT-CIRCUIT VOLTAGE

4.5

4.0

3.5

3.0

2.5

2.0

1.5

1.0

DE485 = V

CC

DE485 = GND

-40

-25

0

25

50

75 85

TEMPERATURE (°C)

FIGURE 13. SUPPLY CURRENT vs TEMPERATURE

FN8776 Rev 1.00

October 21, 2016

Page 12 of 23

ISL33334E, ISL33337E

Typical Performance Curves

V

= 3.3V, T = +25°C, unless otherwise specified (Continued)

A

CC

1640

300

R

= 54Ω, C = 100pF

R

= 54Ω, C = 100pF

DIFF

L

DIFF

L

|t

- t |

PLHZ PHLY

1630

1620

1610

1600

1590

1580

1570

1560

1550

250

200

150

100

50

|t |

- t

PHLZ PLHY

t

DHL

t

DLH

t

DHL

|t

- t

|

DLH DHL

0

-40

-25

0

25

50

75 85

-40

-25

0

25

50

75 85

TEMPERATURE (°C)

FIGURE 14. RS-485, DRIVER PROPAGATION DELAY vs

TEMPERATURE (SLOW DATA RATE)

FIGURE 15. RS-485, DRIVER SKEW vs TEMPERATURE

(SLOW DATA RATE)

24

3.0

R

= 54Ω, C = 100pF

R

= 54Ω, C = 100pF

L

DIFF

L

DIFF

23

22

21

20

19

18

17

16

15

|t

- t |

DLH DHL

2.5

2.0

1.5

1.0

0.5

0

t

DLH

|t

- t

|

PHLZ PLHY

t

DHL

|t

- t

|

PLHZ PHLY

-40

0

50

85

-25

25

75

-40

-25

0

25

50

75 85

TEMPERATURE (°C)

FIGURE 16. RS-485, DRIVER PROPAGATION DELAY vs

TEMPERATURE (FAST DATA RATE)

FIGURE 17. RS-485, DRIVER SKEW vs TEMPERATURE

(FAST DATA RATE)

R

= 54Ω, C = 100pF

L

R

= 54Ω, C = 100pF

L

DIFF

5

0

5

0

DI

5

0

5

0

RO

4

3

2

1

0

4

3

2

1

0

Z

Y

Z

TIME (400ns/DIV)

FIGURE 18. RS-485, DRIVER AND RECEIVER WAVEFORMS,

LOW TO HIGH (SLOW DATA RATE)

FIGURE 19. RS-485, DRIVER AND RECEIVER WAVEFORMS,

HIGH TO LOW (SLOW DATA RATE)

FN8776 Rev 1.00

October 21, 2016

Page 13 of 23

ISL33334E, ISL33337E

Typical Performance Curves

V

= 3.3V, T = +25°C, unless otherwise specified (Continued)

CC A

R

= 54Ω, C = 100pF

L

R

= 54Ω, C = 100pF

L

DIFF

5

0

5

0

DI

5

0

5

0

RO

4

3

2

1

0

4

3

2

1

0

Z

Y

Z

TIME (10ns/DIV)

FIGURE 20. RS-485, DRIVER AND RECEIVER WAVEFORMS,

LOW TO HIGH (FAST DATA RATE)

FIGURE 21. RS-485, DRIVER AND RECEIVER WAVEFORMS,

HIGH TO LOW (FAST DATA RATE)

7.5

250kbps

400kbps

V

+

5.0

2.5

0

5.0

2.5

0

V

+

OUT

BOTH T LOADED WITH 3kΩ TO GND

2 TRANSMITTERS AT 250kbps OR 400kbps

OUTS

OUTPUTS STATIC

BOTH T LOADED WITH 3kΩ TO GND

OUTS

AND AT V+ OR V-

-2.5

-5

-2.5

-5

400kbps

250kbps

V

-

V

-

OUT

-7.5

0

1000

2000

3000

4000

5000

-40

-25

0

25

50

75 85

TEMPERATURE (°C)

LOAD CAPACITANCE (pF)

FIGURE 22. RS-232, TRANSMITTER OUTPUT VOLTAGE vs LOAD

CAPACITANCE

FIGURE 23. RS-232, TRANSMITTER OUTPUT VOLTAGE vs

TEMPERATURE

50

C

= 2000pF, 2 CHANNELS SWITCHING

L

40

5V

0

TxOUT = LOW

TxIN

30

20

5V

0

V

SHORTED TO GND

OUT

10

0

TxOUT/

RxIN

-5V

5V

-10

-20

-30

RxOUT

TxOUT = HIGH

0

-40

-25

0

25

50

75 85

2µs/DIV

TEMPERATURE (°C)

FIGURE 25. RS-232, TRANSMITTER AND RECEIVER WAVEFORMS

AT 250kbps

FIGURE 24. RS-232, TRANSMITTER SHORT-CIRCUIT CURRENT vs

TEMPERATURE

FN8776 Rev 1.00

October 21, 2016

Page 14 of 23

ISL33334E, ISL33337E

Typical Performance Curves

V

= 3.3V, T = +25°C, unless otherwise specified (Continued)

A

CC

58

C

= 1000pF, 2 CHANNELS SWITCHING

V

= ±5V

L

IN

FULL TEMP RANGE

5V

0

57

56

55

54

53

52

51

50

49

TxIN

TxOUT/

RxIN

5V

0

SR IN = 15V/µs

-5V

5V

SR IN = 100V/µs

0

RxOUT

0

500

1000

1500

2000

2µs/DIV

DATA RATE (kbps)

FIGURE 26. RS-232, TRANSMITTER AND RECEIVER WAVEFORMS

AT 400kbps

FIGURE 27. RS-232, RECEIVER OUTPUT +DUTY CYCLE vs DATA

RATE

550

7.5

V

≥ ±4V AND DUTY CYCLE BETWEEN 40% AND 60%

OUT

500

450

400

350

300

250

200

150

100

BOTH T

LOADED WITH 5kΩ TO GND

OUTS

+25°C

V

+

OUT

5

+85°C

2 TRANSMITTERS AT +25°C

2.5

1 TRANSMITTER AT +25°C

2 TRANSMITTERS SWITCHING

0

BOTH T

OUTS

LOADED WITH 5kΩ TO GND, C = 1000pF

L

-2.5

1 TRANSMITTER AT +85°C

2 TRANSMITTERS AT +85°C

+85°C

+25°C

-5

V

-

OUT

-7.5

0

1000

2000

3000

4000

5000

0

100

200

300

400

500

600

LOAD CAPACITANCE (pF)

DATA RATE (kbps)

FIGURE 28. RS-232, TRANSMITTER MAXIMUM DATA RATE vs

LOAD CAPACITANCE

FIGURE 29. RS-232, TRANSMITTER OUTPUT VOLTAGE vs DATA

RATE

Die Characteristics

SUBSTRATE AND QFN PAD POTENTIAL

(POWERED UP):

650

2 TRANSMITTERS SWITCHING

600

BOTH T

LOADED WITH 3kΩ TO GND, C = 1000pF

OUTS

L

GND

550

500

450

400

350

300

250

+85°C

PROCESS:

BiCMOS

+25°C

-40 °C

0

50

200

400

600 650

DATA RATE (kbps)

FIGURE 30. RS-232, TRANSMITTER SKEW vs DATA RATE

FN8776 Rev 1.00

October 21, 2016

Page 15 of 23

ISL33334E, ISL33337E

Typical Application

RS-232 to RS-485 Converter

Detailed Description

Each of the ISL3333XE parts supports dual protocols:

RS-485/RS-422 (port 2) and RS-232 (port 1). RS-485 and

RS-422 are differential (balanced) data transmission standards

for use in high speed (up to 20Mbps) networks, or long haul and

noisy environments. The differential signaling, coupled with

RS-485’s requirement for an extended Common-mode Range

(CMR) of +12V to -7V make these transceivers extremely

tolerant of ground potential differences, as well as voltages

induced in the cable by external fields. Both of these effects are

real concerns when communicating over the RS-485/RS-422

maximum distance of 4000’ (1220m).

The ISL33334E, ISL33337E are ideal for implementing a single

IC 2-wire (Tx Data, Rx Data) protocol converter, because each

port is programmed for a different protocol. Figure 31 illustrates

the simple connections to create a single transceiver RS-232 to

RS-485 converter. Depending on the RS-232 data rate, using an

RS-422 bus as an RS-232 “extension cord” can extend the

transmission distance up to 4000’ (1220m). A similar circuit on

the other end of the cable completes the conversion to/from

RS-232.

+3.3V

+

0.1µF

9, 26

RS-422 is typically a point-to-point (one driver talking to one

receiver on a bus), or a point-to-multireceiver (multidrop)

standard that allows only one driver and up to 10 receivers on

each bus. Because of the one driver per bus limitation, RS-422

networks use a two bus, full duplex structure for bidirectional

communication and the Rx inputs and Tx outputs (no tri-state

required) connect to different busses, as shown in Figure 33.

1

C

0.1µF

1

C1+

V

3

C

0.1µF

CC

3

+

V+

2

C1-

28

C

2

0.1µF

C2+

+

17

24

C

4

V-

27

C2-

0.1µF

+

R1OUT

4 R1IN

5k?

R2IN

NC

R

TxD

R2OUT

Conversely, RS-485 is a true multipoint standard, which allows

up to 32 devices (any combination of drivers - must be

tri-statable - and receivers) on each bus. Now, bidirectional

communication takes place on a single bus, so the Rx inputs

and Tx outputs of a port connect to the same bus lines, as

shown in Figure 32. Port 2 is set to RS-485 /RS-422 mode and

includes one Rx and one Tx.

5

25

RS-232 IN

5k?

6 T1OUT

T1IN

22

23

NC

D

RxD

RS-232 OUT

T2IN

7

T2OUT

D

RS-232 is a point-to-point, single ended (signal voltages

referenced to GND) communication protocol targeting fairly

short (<150’, 46m) and low data rate (<1Mbps) applications.

Port 1 contains two RS-232 transceivers (2 Tx and 2 Rx).

13

12

B

A

RO

18

16

RS-485 IN

R

RE485

11

10

Z

Y

DI

20

19

RS-485 OUT

D

DE485

V

CC

GND

8, 15

NOTE: PINOUT FOR SSOP

FIGURE 31. SINGLE IC RS-232 TO RS-485 CONVERTER

FN8776 Rev 1.00

October 21, 2016

Page 16 of 23

ISL33334E, ISL33337E

GENERIC 1/2 DUPLEX 485 XCVR

RO RE

DE

DI

GENERIC 1/2 DUPLEX 485 XCVR

+3.3V OR +5V

+3.3V

0.1µF

ISL3333XE

+

D

+

0.1µF

R

0.1µF

V

CC

V

CC

GND

V

CC

RO

RE

RO

RE

A

B

R

+3.3V OR +5V

B/Z

Tx/Rx

A/Y

DE

DI

DE

DI

Z

B/Z

A/Y

D

Y

R

T

GND

R

T

FIGURE 32. TYPICAL HALF DUPLEX RS-485 NETWORK

GENERIC 422 Rx (SLAVE)

RO RE

GENERIC FULL DUPLEX 422 XCVR (SLAVE)

+3.3V OR +5V

0.1µF

+3.3V

R

+

ISL3333XE (MASTER)

0.1µF

GND

V

+3.3V OR +5V

CC

A

B

1kΩ

V

CC

R

CC

T

RO

DI

Y

A

B

D

R

DI

Z

DE

Z

Y

R

B

T

R

D

A

RO

GND

RE485

FIGURE 33. TYPICAL RS-422 NETWORK

.

FN8776 Rev 1.00

October 21, 2016

Page 17 of 23

ISL33334E, ISL33337E

SHDN is a global function - affecting both ports - so it is useful

for disabling the RS-232 outputs only if both ports will always

be disabled together and if it is acceptable for the Rx to be

disabled as well.

ISL3333XE Advantages

These dual protocol ICs offer many parametric improvements

vs those offered on competing dual protocol devices. Some of

the major improvements are:

Charge Pumps

• 3.3V Supply Voltage - Eliminates the 5V supply that powers

just the interface IC

The on-chip charge pumps create the RS-232 transmitter

power supplies (typically +5.7/-5.3V) from a single supply as

low as 3.15V and are enabled all the time unless in SHDN via

the SHDN pin. The efficient design requires only four small

0.1µF capacitors for the voltage doubler and inverter

functions. By operating discontinuously (i.e., turning off as

soon as V+ and V- pump up to the nominal values), the charge

pump contribution to I reduces significantly.

• 15kV Bus Pin ESD - Eases board level requirements

• Full Fail-safe RS-485 Rx - Eliminates bus biasing

• Selectable RS-485 Data Rate - Up to 20Mbps, or slew rate

limited for low EMI and fewer termination issues

• High RS-232 Data Rate - >250kbps

CC

• Lower Tx and Rx Skews - Wider, consistent bit widths

Data Rates and Cabling

• Lower I - Max I is 2x to 4x lower than competition

CC CC

Drivers operate at data rates up to 400kbps and are

guaranteed for data rates up to 250kbps. The charge pumps

and drivers are designed such that both drivers in port 1 can

be operated at the rated load and at 250kbps (see Figure 22

on page 14). Figure 22 also shows that drivers can easily two

thousand picofarads at data rates up to 250kbps, while still

delivering compliant ±5V output levels.

• Flow-Through Pinouts - Tx, Rx bus pins on one side, logic pins

on the other, for easy routing to connector/UART

• Packaging - Smaller (QFN) and Pb-free

RS-232 Mode (Port 1)

Rx Features

Receivers operate at data rates up to 2Mbps. They are

designed for a higher data rate to facilitate faster factory

downloading of software into the final product, thereby

improving the user’s manufacturing throughput.

RS-232 receivers invert and convert RS-232 input levels (±3V

to ±25V) to the standard TTL/CMOS levels required by a UART,

ASIC, or µcontroller serial port. Receivers are designed to

operate at faster data rates than the drivers and they feature

very low skews (18ns) so the receivers contribute negligibly to

bit width distortion. Inputs include the standards required 3kΩ

to 7kΩ pull-down resistor, so unused inputs may be left

unconnected. Rx inputs also have built-in hysteresis to

increase noise immunity and to decrease erroneous triggering

due to slowly transitioning input signals.

Figures 25 and 26 illustrate driver and receiver waveforms at

250kbps and 400kbps, respectively. For these graphs, both

drivers of port 1 drive the specified capacitive load and a

receiver in the port.

RS-232 doesn’t require anything special for cabling; just a

single bus wire per transmitter and receiver and another wire

for GND. So an ISL3333XE RS-232 port uses a five conductor

cable for interconnection. Bus terminations are not required,

nor allowed, by the RS-232 standard.

Rx outputs are short-circuit protected and are only tri-statable

when the entire IC is shutdown via the SHDN pin (see Table

Table 3 on page 3 and the “Low Power Shutdown (SHDN)

Mode” on page 20 for more details).

RS-485 Mode (Port 2)

Rx Features

Tx Features

RS-232 drivers invert and convert the standard TTL/CMOS

levels from a UART, or µcontroller serial port to RS-232

compliant levels (±5V minimum). The Tx delivers these

compliant output levels even at data rates of 400kbps, with

loads of 500pF. The drivers are designed for low skew (typically

12% of the 400kbps bit width) and are compliant to the

RS-232 slew rate spec (4 to 30V/µs) for a wide range of load

capacitances. Tx inputs float if left unconnected and may

RS-485 receivers convert differential input signals as small as

200mV, as required by the RS-485 and RS-422 standards, to

TTL/CMOS output levels. The differential Rx provides

maximum sensitivity, noise immunity and common-mode

rejection. Per the RS-485 standard, receiver inputs function

with common-mode voltages from +12V to -7V, regardless of

supply voltage, making them ideal for long networks where

induced voltages are a realistic concern. The RS-485/RS-422

port includes a single receiver (RO).

cause I increases. For the best results, connect unused

CC

inputs to GND.

Worst case receiver input currents are 20% lower than the 1

“unit load” (1mA) RS-485 limit, which translates to a 15kΩ

minimum input resistance.

Tx outputs are short-circuit protected and incorporate a

thermal shutdown feature to protect the IC in situations of

severe power dissipation - see the RS-485 “Tx Features” on

page 19 for more details. Both Tx outputs disable when the IC

enters thermal shutdown.

This receiver includes a “full fail-safe” function that guarantees

a high level receiver output if the receiver inputs are

unconnected (floating), shorted together, or if the bus is

terminated but undriven (i.e., differential voltage collapses to

near zero due to termination). Fail-safe with shorted, or

Drivers also tri-state in SHDN mode (SHDN = 0), or when the

3.3V power supply is off (see Table 3 and the “Low Power

Shutdown (SHDN) Mode” on page 20 section for more details).

FN8776 Rev 1.00

October 21, 2016

Page 18 of 23

ISL33334E, ISL33337E

terminated and undriven inputs is accomplished by setting the

Rx upper switching point at -40mV, thereby ensuring that the

Rx recognizes a 0V differential as a high level.

Nevertheless, for the best jitter performance when driving long

cables, the faster speed option may be preferable, even at

lower data rates. The faster output transitions deliver less

variability (jitter) when loaded with the large capacitance

associated with long cables. Of course, faster transitions

require more attention to ensuring short stub lengths and

quality terminations, so there are trade-offs to be made.

Assuming a jitter budget of 10%, it is likely better to go with

the slow speed option for data rates of 115kbps or less, to

minimize fast edge effects. For higher data rates, or when the

absolute best jitter is required, use the high speed option. The

data rate selection pertains to only port 2.

The Rx output is short-circuit protected and is tri-stated when

the RE485 input is driven low or when the IC is forced into

SHDN via a logic low on the SHDN pin.

Tx Features

The RS-485/RS-422 driver is a differential output device that

delivers at least 1.5V across a 54Ω load (RS-485) and at least

2V across a 100Ω load (RS-422). The drivers feature low

propagation delay skew to maximize bit widths and to

minimize EMI.

Data Rate, Cables and Terminations

RS-485/RS-422 are intended for network lengths up to 4000’

(1220m), but the maximum system data rate decreases as the

transmission length increases. Devices operating at the

maximum data rate of 20Mbps are limited to maximum

lengths of 20-100’ (6-31m), while devices operating at or

below 115kbps can operate at the maximum length of 4000’

(1220m).

To allow multiple drivers on a bus, the RS-485 spec requires

that drivers survive worst case bus contentions undamaged.

The ISL3333XE drivers meet this requirement via driver output

short-circuit current limits and on-chip thermal shutdown

circuitry. The output stages incorporate current limiting

circuitry that ensures that the output current never exceeds the

RS-485 spec, even at the common-mode voltage range

extremes of 12V and -7V. In the event of a major short-circuit

condition, devices also include a thermal shutdown feature that

disables the drivers whenever the die temperature becomes

excessive. This eliminates the power dissipation, allowing the

die to cool. The drivers automatically re-enable after the die

temperature drops about 15 degrees. If the contention persists,

the thermal shutdown/re-enable cycle repeats until the fault is

cleared. Receivers stay operational during thermal shutdown.

Higher data rates require faster edges, so both of the

ISL3333XE versions offer an edge rate capable of 20Mbps

data rates. These ICs also offer a slew rate limited option to

minimize problems at slower data rates. Nevertheless, for the

best jitter performance when driving long cables, the faster

speed settings may be preferable, even at low data rates. See

the “RS-485 Slew Rate Limited Data Rates” section for details.

Twisted pair is the cable of choice for RS-485/RS-422

networks. Twisted pair cables tend to pick up noise and other

electromagnetically induced voltages as common-mode

signals, which are effectively rejected by the differential

receivers in these ICs.

RS-485 multidriver operation also requires drivers to include

tri-state functionality, so port 2 has a DE485 pin to control this

function. If the driver is used in an RS-422 network, such that

driver tri-state isn’t required, then the DE485 pin should be

connected to V , through a 1kΩ resistor, to keep the Tx in the

CC

enabled state. Drivers are also tri-stated when the IC is in

SHDN, or when the 3.3V power supply is off.

The preferred cable connection technique is “daisy-chaining”,

where the cable runs from the connector of one device directly

to the connector of the next device, such that cable stub

lengths are negligible. A “backbone” structure, where stubs

run from the main backbone cable to each device’s connector,

is the next best choice, but care must be taken to ensure that

each stub is electrically “short”. See Table 4 for recommended

maximum stub lengths for each speed option.

Speed Options

The ISL3333XE offer two RS-485 speed options selectable via

the SLOW485 pin; “Fast” mode (SLOW485 = 1) selects high

slew rate driver outputs optimized for 20Mbps data rates while

“Slow” mode uses slew rate limiting designed for 115kbps

operation. See the “RS-485 Slew Rate Limited Data Rates”

and “Data Rate, Cables and Terminations” sections for more

information.

TABLE 4. RECOMMENDED STUB LENGTHS

MAXIMUM STUB LENGTH

SPEED OPTION

SLOW

ft (m)

Receiver performance is the same for both speed options.

350-500 (107-152)

1-3 (0.3 - 0.9)

RS-485 Slew Rate Limited Data Rates

FAST

These ICs allow the user to select fast Tx output transitions

optimized for a 20Mbps data rate, or slew rate limited

transitions optimized for a data rate of 115kbps. The 20Mbps

fast edges may increase EMI and reflection issues, even

though fast transitions aren’t required at the lower data rates

used by many applications. Choosing the slew limited edges

for lower data rates permits longer unterminated networks, or

longer stubs off terminated busses and helps minimize EMI

and reflections.

Proper termination is imperative to minimize reflections when

using the 20Mbps speed option. Short networks using the slow

speed option need not be terminated, but terminations are

recommended unless power dissipation is an overriding

concern. Note that the RS-485 spec allows a maximum of two

terminations on a network, otherwise the Tx output voltage

may not meet the required V

.

OD

In point-to-point, or point-to-multireceiver (RS-422) networks,

the main cable should be terminated in its characteristic

FN8776 Rev 1.00

October 21, 2016

Page 19 of 23

ISL33334E, ISL33337E

impedance (typically 120Ω) at the end farthest from the driver.

In multireceiver applications, stubs connecting receivers to the

main cable should be kept as short as possible, but definitely

shorter than the limits shown in Table 4. Multipoint (RS-485)

systems require that the main cable be terminated in its

characteristic impedance at both ends. Again, keep stubs

connecting a transceiver to the main cable as short as possible

and refer to Table 4. Avoid “star” and other configurations,

where there are many “ends” which would require more than

the two allowed terminations to prevent reflections.

Flow-Through Pinouts

Even the ISL3333XE pinouts are features, in that the true

flow-through design simplifies board layout. Having the bus

pins all on one side of the package for easy routing to a cable

connector and the Rx outputs and Tx inputs (logic pins) on the

other side for easy connection to a UART, avoids costly and

problematic crossovers. Competing “flow-through” pinouts mix

logic and bus pin inputs on one side of the package and logic

and bus pin outputs on the other side. This forces the designer

to route four traces from the right side of the IC around the IC

to the cable connector. Figure 35 illustrates the flow-through

nature of the ISL3333XE’s pinout.

Active Low Rx Enable (RE485)

In many RS-485 applications, especially half duplex

configurations, users like to implement “echo suppression” by

disabling the corresponding receiver while its driver is

transmitting data. This function is available on the ISL3333XE

parts via an active low RE485 pin for port 2. The active low

function simplifies direction control, by allowing a single GPIO

line to provide a Tx/Rx direction control signal. Figure 34

details the advantage of using the RE485 pin.

ISL33334E

R2OUT

R1OUT

T2IN

R1IN

R2IN

T1OUT

UART

OR

ASIC

T2OUT

T1IN

Y

Z

OR

DI

+3.3V

D

µCONTROLLER

ISL3333XE

+

RO

0.1µF

A

B

R

V

CC

RO

RE

A

B

R

FIGURE 35. ILLUSTRATION OF FLOW-THROUGH PINOUT

Tx/Rx

DE

DI

Z

Y

Low Power Shutdown (SHDN) Mode

D

The SHDN pin is driven low to place the IC (both ports) in the

SHDN mode and the already low supply current drops to as low

as 40µA. If this functionality isn’t desired, the SHDN pin should

be connected to V_CCthrough a 1kΩ resistor. SHDN disables the

Tx and Rx outputs and disables the charge pumps, so V+

GND

FIGURE 34. USING ACTIVE LOW RX ENABLE

collapses to V and V- collapses to GND.

CC

All but 10µA of SHDN supply current is due to control input

(SHDN, SLOW485, DE485) pull-up resistors (~10µA/resistor

when the input = 0V), so SHDN supply current varies

depending on the ISL3333XE configuration. For example, the

RS-485 drivers are disabled in SHDN, so driving the DE485 pin

high during this time reduces the SHDN supply current. The

Additional Features

High ESD

All pins on the ISL3333XE include ESD protection structures

rated at ±2.5kV (HBM), which is good enough to survive ESD

events commonly seen during manufacturing. But the bus pins

(Tx outputs and Rx inputs) are particularly vulnerable to ESD

events because they connect to an exposed port on the

exterior of the finished product. Simply touching the port pins,

or connecting a cable, can destroy an unprotected port.

ISL3333XE bus pins are fitted with advanced structures that

deliver ESD protection in excess of ±15kV (HBM), without

interfering with any signal in the RS-485 or the RS-232 range.

This high level of protection may eliminate the need for board

level protection, or at the very least will increase the

spec table indicates the SHDN I for the worst case

CC

configuration.

When enabling from SHDN, allow at least 25µs for the charge

pumps to stabilize before transmitting RS-232 data. The

charge pumps aren’t used by the RS-485 port, so the

transceiver is ready to send or receive data in less than 2µs,

which is much faster than competing devices that require the

charge pump for all modes of operation.

robustness of any board level scheme.

Small Packages

Many competing dual protocol devices are only available in

monstrously large 24 to 28 Ld SOIC packages. The ISL33334’s

28 Ld SSOP is 50% smaller than even a 24 Ld SOIC and the

ISL33337E’s small 6x6mm QFN footprint is 80% smaller than

a 28 Ld SOIC.

FN8776 Rev 1.00

October 21, 2016

Page 20 of 23

ISL33334E, ISL33337E

Revision History The revision history provided is for informational purposes only and is believed to be accurate, but not warranted.

Please visit our website to make sure you have the latest revision.

DATE

REVISION

FN8776.1

CHANGE

October 21, 2016

Added Related Literature section on page 1.

Added Table 2 on page 2.

Added Tape and Reel column to Ordering information table.

September 29, 2015

FN8776.0

Initial Release

About Intersil

Intersil Corporation is a leading provider of innovative power management and precision analog solutions. The company's products

address some of the largest markets within the industrial and infrastructure, mobile computing and high-end consumer markets.

For the most updated datasheet, application notes, related documentation and related parts, please see the respective product

information page found at www.intersil.com.

You may report errors or suggestions for improving this datasheet by visiting www.intersil.com/ask.

Reliability reports are also available from our website at www.intersil.com/support.

All trademarks and registered trademarks are the property of their respective owners.

For additional products, see www.intersil.com/en/products.html

Intersil products are manufactured, assembled and tested utilizing ISO9001 quality systems as noted

in the quality certifications found at www.intersil.com/en/support/qualandreliability.html

Intersil products are sold by description only. Intersil may modify the circuit design and/or specifications of products at any time without notice, provided that such

modification does not, in Intersil's sole judgment, affect the form, fit or function of the product. Accordingly, the reader is cautioned to verify that datasheets are

current before placing orders. Information furnished by Intersil is believed to be accurate and reliable. However, no responsibility is assumed by Intersil or its

subsidiaries for its use; nor for any infringements of patents or other rights of third parties which may result from its use. No license is granted by implication or

otherwise under any patent or patent rights of Intersil or its subsidiaries.

For information regarding Intersil Corporation and its products, see www.intersil.com

FN8776 Rev 1.00

October 21, 2016

Page 21 of 23

ISL33334E, ISL33337E

For the most recent package outline drawing, see L40.6x6.

Package Outline Drawing

L40.6x6

40 LEAD QUAD FLAT NO-LEAD PLASTIC PACKAGE

Rev 3, 10/06

4X

4.5

6.00

0.50

36X

A

6

B

31

40

PIN #1 INDEX AREA

6

30

1

PIN 1

INDEX AREA

4 . 10 ± 0 . 15

21

10

0.15

(4X)

11

20

0.10 M C A B

TOP VIEW

40X 0 . 4 ± 0 . 1

4

0 . 23 +0 . 07 / -0 . 05

BOTTOM VIEW

SEE DETAIL "X"

C

0.10

C

0 . 90 ± 0 . 1

BASE PLANE

( 5 . 8 TYP )

(

SEATING PLANE

0.08 C

SIDE VIEW

4 . 10 )

( 36X 0 . 5 )

5

C

0 . 2 REF

( 40X 0 . 23 )

0 . 00 MIN.

0 . 05 MAX.

( 40X 0 . 6 )

DETAIL "X"

TYPICAL RECOMMENDED LAND PATTERN

NOTES:

1. Dimensions are in millimeters.

Dimensions in ( ) for Reference Only.

2. Dimensioning and tolerancing conform to AMSE Y14.5m-1994.

3.

Unless otherwise specified, tolerance : Decimal ± 0.05

4. Dimension b applies to the metallized terminal and is measured

between 0.15mm and 0.30mm from the terminal tip.

Tiebar shown (if present) is a non-functional feature.

5.

6.

The configuration of the pin #1 identifier is optional, but must be

located within the zone indicated. The pin #1 indentifier may be

either a mold or mark feature.

FN8776 Rev 1.00

October 21, 2016

Page 22 of 23

ISL33334E, ISL33337E

Shrink Small Outline Plastic Packages (SSOP)

M28.209 (JEDEC MO-150-AH ISSUE B)

28 LEAD SHRINK SMALL OUTLINE PLASTIC PACKAGE

N

INDEX

AREA

0.25(0.010)

M

B M

H

E

INCHES

MILLIMETERS

GAUGE

PLANE

SYMBOL

MIN

MAX

0.078

-

MIN

-

MAX

2.00

-

NOTES

-B-

A

A1

A2

B

-

1

2

3

0.002

0.065

0.009

0.004

0.390

0.197

0.05

1.65

0.22

0.09

9.90

5.00

-

L

0.072

0.014

0.009

0.413

0.220

1.85

0.38

0.25

10.50

5.60

-

0.25

0.010

SEATING PLANE

A

9

-A-

D

C

D

E

-

3

-C-

4



A2

e

0.026 BSC

0.65 BSC

-

A1

C

H

L

0.292

0.022

0.322

0.037

7.40

0.55

8.20

0.95

-

B

0.10(0.004)

6

0.25(0.010) M

C

A M B S

N



28

7

NOTES:

0°

8°

0°

8°

-

1. Symbols are defined in the “MO Series Symbol List” in Section 2.2

of Publication Number 95.

Rev. 2 6/05

2. Dimensioning and tolerancing per ANSI Y14.5M-1982.

3. Dimension “D” does not include mold flash, protrusions or gate

burrs. Mold flash, protrusion and gate burrs shall not exceed

0.20mm (0.0078 inch) per side.

4. Dimension “E” does not include interlead flash or protrusions.

Interlead flash and protrusions shall not exceed 0.20mm (0.0078

inch) per side.

5. The chamfer on the body is optional. If it is not present, a visual

index feature must be located within the crosshatched area.

6. “L” is the length of terminal for soldering to a substrate.

7. “N” is the number of terminal positions.

8. Terminal numbers are shown for reference only.

9. Dimension “B” does not include dambar protrusion. Allowable

dambar protrusion shall be 0.13mm (0.005 inch) total in excess of

“B” dimension at maximum material condition.

10. Controlling dimension: MILLIMETER. Converted inch dimensions

are not necessarily exact.

For the most recent package outline drawing, see M28.209.

FN8776 Rev 1.00

October 21, 2016

Page 23 of 23


型号：	ISL33334EIAZ-T
厂家：	RENESAS TECHNOLOGY CORP
描述：	3.3V, ±15kV ESD Protected, Two Port, Dual Protocol (RS-232/RS-485) Transceiver in a SSOP Package; SSOP28; Temp Range: -40° to 85°C 接口集成电路
文件：	总23页 (文件大小：1401K)
中文：	中文翻译
下载：	下载PDF数据表文档文件

ISL33334EIAZ-T [RENESAS]

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