CN-0313 [ADI]

EMC Compliant RS-485 Transceiver Protection Circuits; EMC兼容RS- 485收发器保护电路


型号：	CN-0313
厂家：	ADI
描述：	EMC Compliant RS-485 Transceiver Protection Circuits EMC兼容RS- 485收发器保护电路
文件：	总5页 (文件大小：271K)
中文：	中文翻译
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Circuit Note

CN-0313

Devices Connected/Referenced

Circuits from the Lab™ reference circuits are engineered and

tested for quick and easy system integration to help solve today’s

analog, mixed-signal, and RF design challenges. For more

information and/or support, visit www.analog.com/CN0313.

15 kV ESD-Protected, 3.3 V,12 Mbps,

EIA RS-485 Transceiver

ADM3485E

EMC Compliant RS-485 Transceiver Protection Circuits

using the ADM3485E transceiver. Each solution was tested and

EVALUATION AND DESIGN SUPPORT

characterized to ensure that the dynamic interaction between

the transceiver and the protection circuit components functions

correctly together to protect against the electrostatic discharge

(ESD), electrical fast transients (EFT), and surge immunity

specified in IEC 61000-4-2, IEC 61000-4-4, and IEC 61000-4-5,

respectively. The circuits offer proven protection for RS-485

interfaces using the ADM3485E to the ESD, EFT, and surge

levels often encountered in harsh environments.

Circuit Evaluation Boards

CN-0313 Circuit Evaluation Board (EVAL-CN0313-SDPZ)

Design and Integration Files

Schematics, Layout Files, Bill of Materials

CIRCUIT FUNCTION AND BENEFITS

The circuits shown in Figure 1 demonstrate proven and tested

electromagnetic compatibility (EMC) compliant solutions for

three protection levels for popular RS-485 communication ports

ADM3485E

TBU

TBU-CA065-200-WH

120Ω

TISP

TISP4240M3BJR-S

TVS

CDS0T23-SM712

TVS

CDS0T23-SM712

PROTECTION SCHEME 1. TVS

PROTECTION SCHEME 2. TVS/TBU/TISP

ADM3485E

TBU

TBU-CA065-200-WH

120Ω

GDT

2038-15-SM-RPLF

TVS

CDS0T23-SM712

PROTECTION SCHEME 3. TVS/TBU/GDT

Figure 1. Three EMC Compliant ADM3485E Protection Circuits (Simplified Schematic, All Connections Not Shown)

Rev. 0

Circuits from the Lab™ circuits from Analog Devices have been designed and built by Analog Devices

engineers. Standard engineering practices have been employed in the design and construction of

each circuit, andtheir function andperformance have been tested and verifiedin a lab environment at

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Tel: 781.329.4700

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www.analog.com

CN-0313

Circuit Note

Table 1. Protection Levels Offered by Each of the Three

Protection Circuits in Figure 1

CIRCUIT DESCRIPTION

The RS-485 bus standard is one of the most widely used physical

layer bus designs in industrial and instrumentation applications.

RS-485 offers differential data transmission between multiple

systems often over very long distances. Applications for RS-485

include process control networks; industrial automation; remote

terminals; building automation, such as heating, ventilation, air

conditioning (HVAC) and security systems; motor control; and

motion control.

Protection Scheme ESD

EFT (kV) Surge (kV)

1. TVS

8 kV contact,

15 kV air discharge

8 kV contact,

15 kV air discharge

2. TVS/TBU/TISP

3. TVS/TBU/GDT

8 kV contact,

15 kV air discharge

Figure 2 shows a photo of the EVAL-CN0313-SDPZ board. There

are three ADM3485E devices on the board, one for each

protection scheme. Each protection scheme provides ESD and

EFT protection as described and increasing levels of surge

protection.

In these real systems, lightning strikes, power source fluctuations,

inductive switching, and electrostatic discharge can cause

damage to communications ports by generating large transient

voltages. Designers must ensure that equipment does not just

work in ideal conditions, but it must also work in real-world

conditions. To ensure that these designs can work in electrically

harsh environments, EMC regulations must be met.

A complete design support package for the EVAL-CN0313-

SDPZ board including schematics, layout files, and bill of

materials can be found at www.analog.com/CN0313-

DesignSupport.

Many EMC problems are not simple or obvious and must be

considered at the start of the product development cycle. Proper

solutions and protection circuits must be part of the total design

effort and not left to the last minute. The protection circuits

must incorporate the input and output structure of the specific

transceiver manufacturer as part of the design.

The IEC 61000 specifications define the set of EMC immunity

requirements. Within this set of specifications, designers must

be concerned with the following three types of high voltage

transients for data communication lines:

•

IEC 61000-4-2 electrostatic discharge (ESD)

IEC 61000-4-4 electrical fast transients (EFT)

IEC 61000-4-5 surge immunity

ESD and EFT have similar rise times, pulse widths, and energy

levels. The surge transient has longer rise times and pulse widths; as

a result, the surge transient energy can be three to four orders of

magnitude larger than the energy in an ESD or EFT transient.

Due to the similarities between ESD and EFT transients, the

design of the circuit protection can be similar. However, due to

the high energy associated with surge transients, they must be

dealt with differently.

Each solution protects data ports to ESD voltages of 8 kV

contact and 15 kV air discharge, and EFT voltages of 2 kV. The

different solutions provide an increased level of surge

protection up to 6 kV. Protection levels for the circuits are

summarized in Table 1.

Figure 2. EVAL-CN0313-SDPZ Board

Rev. 0 | Page 2 of 5

Circuit Note

CN-0313

The ADM3485E is a 3.3 V, low power data transceiver suitable

for half-duplex communication on multipoint transmission lines.

It has a data rate up to 12 Mbps with a common-mode range on

the bus pins (A and B) of −7 V to +12 V. Data transmits on the

DI pin, and it is received on the RO pin. Both the driver and

receiver outputs can be enabled or disabled, that is, put into a

high impedance state, by changing the logic levels on the DE

In the first protection circuit, shown in Figure 1 as TVS, it uses one

component, the Bourns CDSOT23-SM712. This is the transient

voltage suppressor (TVS) array shown on the EVAL-CN0313-

SDPZ. It consists of two bidirectional TVS diodes optimized to

protect RS-485 systems with minimal overstress while allowing

the full range of the RS-485 signal and common-mode excursions.

The TVS has high impedance to ground in normal operating

conditions. When an overvoltage occurs, the TVS enters into

avalanche breakdown mode and clamps the pin voltage to a safe

predetermined level. It then diverts the transient current away

from the ADM3485E to ground.

and

pins, respectively.

Power and ground are connected via a screw-wire connector (V_CC

and GND). This connector supplies all three ADM3485E devices.

Logic inputs DE and

are set using LK1 to LK6. For each

This protection scheme offers up to 8 kV contact and15 kV air

discharge ESD, 2 kV EFT, and 1 kV surge protection.

ADM3485E, LK2, LK4, and LK6 relate to DE and LK1, LK3, and

LK5 relate to . For each link, Position A connects the logic pin

As described in the CDSOT23-SM712 data sheet, the part is

designed specifically for RS-485 devices. The next two protection

schemes add to the CDSOT23-SM712 to provide higher levels

of circuit protection against surge.

to V_CC, Position B connects the logic pin to GND, and Position C

connects the logic pin to the four terminal, side screw-wire

connector. The input DI and output RO pins are connected

directly to the four terminal screw connector.

In the second scheme, shown in Figure 1 as TVS/TBU/TISP,

the CDSOT23-SM712 TVS provides secondary protection, and

Bourns TISP4240M3BJR-S provides the primary protection. The

TISP4240M3BJR-S is a totally integrated surge protector (TISP).

The TISP is a solid-state thyristor. When its predetermined voltage

is exceeded, the TISP provides a low impedance path to ground,

diverting a majority of the transient energy away from the

ADM3485E.

The EVAL-CN0313-SDPZ is also compatible with the Analog

Devices, Inc., ezLINX™ board (EZLINX-IIIDE-EBZ) and the

system development platform (EVAL-SDP-CB1Z). Connector J8

links the UART and GPIO interfaces on the SDP or the ezLINX

board to the logic I/O of the ADM3485E devices. The I/O

connections and jumper configurations are shown in Table 2.

Table 2. ezLINX and SDP I/O Connections and Jumper

Configurations

Bourns TBU-CA065-200-WH transient blocking unit (TBU) is

a nonlinear overcurrent protection device between the primary

and secondary protection devices that ensures coordination

occurs. The TBU is an overcurrent blocking device that becomes

an open circuit at a predefined current. In blocking mode, TBU

has very high impedance to block transient energy. This protection

scheme offers up to 8 kV contact and15 kV air discharge ESD,

2 kV EFT, and 4 kV surge protection.

ADM3485E

I/O Pin

SDP/ezLINX Connector Selection

TVS

UART_RX

GPIO_0

LK7 (A)

LK1 (C)

LK2 (C)

LK8 (A)

LK7 (B)

LK3 (C)

LK4 (C)

LK8 (B)

LK7 (C)

LK5 (C)

LK6 (C)

LK8 (C)

GPIO_3

UART_TX

UART_RX

GPIO_1

TVS/TBU/TISP RO

GPIO_4

The third protection scheme, shown in Figure 1 as TVS/TBU/

GDT, operates in a similar fashion to Protection Scheme 2. In

this scheme, a gas discharge tube (GDT) is used instead of the

TISP. The GDT protects to higher overvoltages and overcurrents

than the TISP described in the previous protection scheme.

A GDT is a gas discharge plasma device that provides a low

impedance path to ground to protect against over voltage

transients. The selected GDT is the Bourns 2038-15-SM-RPLF.

UART_TX

UART_RX

GPIO_2

TVS/TBU/GDT RO

GPIO_5

UART_TX

The ADM3485E transmitter and receiver share the same differential

bus pins (A and B). The protection circuitry is used to protect

these bus pins.

This third protection scheme offers up to 8 kV contact and

15 kV air discharge ESD, 2 kV EFT, and 6 kV surge protection.

The ADM3485E has a 120 Ω termination attached to the bus pins.

Rev. 0 | Page 3 of 5

CN-0313

Circuit Note

For IEC 61000-4-4 EFT testing, a capacitive coupling clamp is

used to couple the EFT bursts onto the cable connected to the

bus lines. The coupling capacitance of the clamp depends on the

cable diameter, material of the cables, and cable shielding.

CIRCUIT EVALUATION AND TEST

Apply 3.3 V to V_CCto power the EVAL-CN0313-SDPZ board.

The voltage can be checked on the V_CCtest points near each

ADM3485E. The transmit and receive paths can be tested by

connecting one of the ADM3485E circuits as shown in Figure 3.

A signal or pattern generator can be connected to DI. The outputs

of the driver can be monitored on the A and B test points, and the

output of the receiver can be monitored on the RO test point.

Jumper configurations are also shown in Figure 3. This test

setup can apply to any of the three circuits.

IEC 61000-4-5 surge testing implies the use of a coupling/

decoupling network (CDN) to couple the surge transient into

the bus pins. According to the specification, this must be done

using two 80 Ω resistors for a two port test. Figure 4 shows the

test setup for surge testing. Connect the CDN to the A and B

terminals, and the common of the surge generator to the

ground connection of the four terminal screw connector.

SIGNAL

GENERATOR

ADM3485E

CDN

80Ω

PROTECTION

COMPONENTS

3.3V

POWER

SUPPLY

OSCILLOSCOPE

120Ω

80Ω

Figure 4. IEC 61000-4-5 Surge CDN to ADM3485E Setup

All protection circuits described were characterized in the lab

with the ADM3485E and verified by an external independent

EMC compliance test house.

Figure 3. Transmit and Receive Test Setup

For further information on the ezLINX iCoupler® isolated interface

development environment, go to

http://wiki.analog.com/resources/eval/ezlinx.

According to IEC 61000-4-2, ESD testing implies using two

coupling methods, contact discharge and air gap discharge.

Contact discharge implies the discharge gun is placed in direct

connection with the port being tested. With air discharge, the

charged electrode of the discharge gun is moved toward the

port under test until a discharge occurs developing an arc across

the air gap. Apply discharges to the screw terminal connector of

each bus line.

Information on other important EMC issues can be found at

http://www.analog.com/rs485emc.

Rev. 0 | Page 4 of 5

Circuit Note

CN-0313

Data Sheets and Evaluation Boards

ADM3485E Data Sheet

LEARN MORE

CN-0313 Design Support Package:

http://www.analog.com/CN0313-DesignSupport

System Development Platform (EVAL-SDP-CB1Z)

ezLINX™ iCoupler® Isolated Interface Development

Environment, ezLINX Board Quick Start Guide

ezLINX™ iCoupler® Isolated Interface Development

Environment (EZLINX-IIIDE-EBZ)

Certified EMC Compliant RS-485 Interface Design Tool

UG-400 User Guide, ezLINX™ iCoupler® Isolated Interface

Development Environment, Analog Devices.

Marais, Hein. Application Note AN-960. RS-485/RS-422 Circuit

Implementation Guide. Analog Devices, Inc.

CDSOT23-SM712—Surface Mount TVS Diode Data Sheet,

Bourns

Electromagnetic Compatibility (EMC) Part 4-2: Testing and

Measurement Techniques–Electrostatic Discharge Immunity

Test (IEC 61000-4-2)

TISP4xxxM3BJ Overvoltage Protector Series (TISP4240M3BJR-S)

Data Sheet, Bourns

Electromagnetic Compatibility (EMC) Part 4-4: Testing and

Measurement Techniques–Electrical Fast Transient/Burst

Immunity Test (IEC 61000-4-4)

TBU-CA Series—TBU® High Speed Protectors (TBU-CA065-

200-WH) Data Sheet, Bourns

2038 Series Miniature Symmetrical Three Electrode Surface

Mount Gas Discharge Tube (2038-15-SM-RPLF) Data Sheet,

Bourns

Electromagnetic Compatibility (EMC) Part 4-5: Testing and

Measurement Techniques–Surge Immunity Test (IEC 61000-4-5)

REVISION HISTORY

2/13—Revision 0: Initial Version

(Continued from first page) Circuits from the Lab circuits are intended only for use with Analog Devices products and are the intellectual property of Analog Devices or its licensors. While you

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registered trademarks are the property of their respective owners.

CN11250-0-2/13(0)

Rev. 0 | Page 5 of 5

CN-0313 [ADI]

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