FODM3063R1 - Fairchild - Datasheet.Support

FODM3062, FODM3063, FODM3082, FODM3083 — 4-Pin Full Pitch Mini-Flat Package Zero-Cross Triac Driver Output Optocouplers

FODM3062, FODM3063, FODM3082, FODM3083 Rev. 1.0.9

September 2010

FODM3062, FODM3063, FODM3082, FODM3083

4-Pin Full Pitch Mini-Flat Package Zero-Cross

Triac Driver Output Optocouplers

Features

■

dv/dt of 600V/µs guaranteed

■

Compact 4-pin surface mount package

(2.4mm maximum standoff height)

■

Zero voltage crossing

■

Peak blocking voltage: 600V (FODM306X)

800V (FODM308X)

■

Available in tape and reel quantities of 2500

■

C-UL, UL and VDE certiﬁcations pending

Applications

■

Solenoid/valve controls

■

Lighting controls

■

Static power switches

■

AC motor drives

■

Temperature controls

■

E.M. contactors

■

AC motor starters

■

Solid state relays

Description

The FODM306X and FODM308X series consist of an

infrared emitting diode optically coupled to a monolithic

silicon detector performing the function of a zero voltage

crossing bilateral triac driver, and is housed in a compact

4-pin mini-ﬂat package. The lead pitch is 2.54mm. They

are designed for use with a triac in the interface of logic

systems to equipment powered from 115/240 VAC lines,

such as solid state relays, industrial controls, motors,

solenoids and consumer appliances.

Package Dimensions

4.40±0.20

2.54±0.25

3.60±0.30

2.00±0.20

0.10±0.10 0.40±0.10

5.30±0.30

7.00+0.2

–0.7

0.20±0.05

MAIN TERM.

ANODE

CATHODE 3

4MAIN TERM.

ZERO

CROSSING

CIRCUIT

Note:

All dimensions are in millimeters.

FODM3062, FODM3063, FODM3082, FODM3083 Rev. 1.0.9 2

FODM3062, FODM3063, FODM3082, FODM3083 — 4-Pin Full Pitch Mini-Flat Package Zero-Cross Triac Driver Output Optocouplers

Absolute Maximum Ratings

= 25°C unless otherwise speciﬁed)

Stresses exceeding the absolute maximum ratings may damage the device. The device may not function or be

operable above the recommended operating conditions and stressing the parts to these levels is not recommended.

In addition, extended exposure to stresses above the recommended operating conditions may affect device reliability.

The absolute maximum ratings are stress ratings only.

Symbol Parameter Rating Units

TOTAL PACKAGE

STG

Storage Temperature -55 to +150 °C

OPR

Operating Temperature -40 to +100 °C

EMITTER

F (avg)

Continuous Forward Current 60 mA

F (pk)

Peak Forward Current (1µs pulse, 300pps.) 1 A

Reverse Input Voltage 6 V

Power Dissipation (No derating required over operating temp. range) 100 mW

DETECTOR

T(RMS)

On-State RMS Current 70 mA (RMS)

DRM

Off-State Output Terminal Voltage FODM3062/FODM3063 600 V

FODM3082/FODM3083 800

Power Dissipation (No derating required over operating temp. range) 300 mW

FODM3062, FODM3063, FODM3082, FODM3083 Rev. 1.0.9 3

FODM3062, FODM3063, FODM3082, FODM3083 — 4-Pin Full Pitch Mini-Flat Package Zero-Cross Triac Driver Output Optocouplers

Electrical Characteristics

= 25°C)

Individual Component Characteristics

Transfer Characteristics

Zero Crossing Characteristics

Isolation Characteristics

*All typicals at 25°C.

Notes:

1. Test voltage must be applied within dv/dt rating.

2. This is static dv/dt. See Figure 1 for test circuit. Commutating dv/dt is function of the load-driving thyristor(s) only.

3. All devices are guaranteed to trigger at an I

value less than or equal to max I

. Therefore, recommended operating

lies between max I

(10mA for FODM3062/82, 5mA for FODM3063/83) and absolute max I

(60 mA).

4. Steady state isolation voltage, V

ISO

, is an internal device dielectric breakdown rating. For this test, pins 1 & 2 are

common, and pins 3 & 4 are common.

Symbol Parameter Test Conditions Min. Typ.* Max. Units

EMITTER

Input Forward Voltage I

= 30mA 1.5 V

Reverse Leakage Current V

= 6V 100 µA

DETECTOR

DRM1

Peak Blocking Current,

Either Direction Rated V

DRM

, I

= 0

(1)

500 nA

dV/dt Critical Rate of Rise of

Off-State Voltage I

= 0 (Figure 1)

(2)

600 V/µs

Symbol DC Characteristics Test Conditions Device Min. Typ.* Max. Units

LED Trigger Current Main Terminal

Voltage = 3V

(3)

FODM3062 10 mA

FODM3082

FODM3063 5

FODM3083

Holding Current,

Either Direction

All 300 µA

Peak On-State Voltage,

Either Direction

= Rated I

= 100mA peak

All 3 V

Symbol Characteristics Test Conditions Device Min. Typ.* Max. Units

Inhibit Voltage,

MT1-MT2 Voltage

above which device

will not trigger

= Rated I

All 20 V

IDRM2 Leakage in Inhibit

State

= Rated I

Rated VDRM,

Off-State

All 2 mA

Characteristics Test Conditions Symbol Device Min. Typ.* Max. Units

Steady State Isolation

Voltage

(4)

(1 Minute)

R.H. = 40% to 60%

ISO

All 3750 VRMS

FODM3062, FODM3063, FODM3082, FODM3083 Rev. 1.0.9 4

FODM3062, FODM3063, FODM3082, FODM3083 — 4-Pin Full Pitch Mini-Flat Package Zero-Cross Triac Driver Output Optocouplers

Typical Performance Curves

Fig. 1 LED Forward Voltage vs. Forward Current Fig. 2 Leakage Current vs. Ambient Temperature

Fig. 3 Holding Current vs. Ambient Temperature Fig. 4 Trigger Current vs. Ambient Temperature

IF - FORWARD CURRENT (mA)

110100

VF - FORWARD VOLTAGE (V)

0.9

1.0

1.1

1.2

1.3

1.4

1.5

1.6

1.8

1.7

= -40°C

= 25°C

= 100°C

TA - AMBIENT TEMPERATURE (°C)

-40 -20 0 20 406080100

IDRM - LEAKAGE CURRENT (nA)

0.1

100

1000

VDRM = 600V

TA - AMBIENT TEMPERATURE (°C)

-40 -20 100

IH - HOLDING CURRENT (NORMALIZED)

0.1

1.0

020406080

NORMALIZED TO TA = 25°C

TA - AMBIENT TEMPERATURE (°C)

-40 -20 0 20 40 60 80

IFT - TRIGGER CURRENT (NORMALIZED)

0.8

0.6

0.8

1.0

1.2

1.4

1.6

VTM = 3V

NORMALIZED TO TA = 25°C

100

FODM3062, FODM3063, FODM3082, FODM3083 Rev. 1.0.9 5

FODM3062, FODM3063, FODM3082, FODM3083 — 4-Pin Full Pitch Mini-Flat Package Zero-Cross Triac Driver Output Optocouplers

Typical Performance Curves

(Continued)

Fig. 7 On-State Characteristics

VTM - ON-STATE VOLTAGE (V)

-4 -3 -2 -1 01234

ITM - ON-STATE CURRENT (mA)

-800

-600

-400

-200

200

400

600

800

TA = 25°C

Fig. 5 LED Current Required to Trigger vs. LED Pulse Width Fig. 6 Off-State Output Terminal Voltage vs. Ambient Temperature

PWIN

- LED TRIGGER PULSE WIDTH (°C)

100101

IFT - LED TRIGGER CURRENT (NORMALIZED)

IN >> 100µsNORMALIZED TO PW

T= 25°CA

NORMALIZED TO T = 25°C

TA - AMBIENT TEMPERATURE (°C)

VDRM

- OFF-STATE OUTPUT TERMINAL VOLTAGE

(NORMALIZED)

0.6

0.7

0.8

0.9

1.0

1.1

1.2

1.3

1.4

-40 -20

020406080100

FODM3062, FODM3063, FODM3082, FODM3083 Rev. 1.0.9 6

FODM3062, FODM3063, FODM3082, FODM3083 — 4-Pin Full Pitch Mini-Flat Package Zero-Cross Triac Driver Output Optocouplers

Typical Applications

Figure 8. Static dv/dt Test Circuit

Vdc

800V (FODM3082)

(FODM3083)

600V (FODM3062)

(FODM3063)

R = 10 kΩ

CTEST

X100

SCOPE

PROBE

PULSE

INPUT MERCURY

WETTED

RELAY

378V (FODM3062, FODM3063)

504V (FODM3082, FODM3083)

0 VOLTS

APPLIED VOLTAGE

WAVEFORM

Vmax =

dv/dt = 0.63 Vmax

RTEST

D.U.T.D.U.T.

τRC

= 800V (FODM3082, FODM3083)

= 600V (FODM3062, FODM3063)

= 378

τRC (FODM3062, FODM3063)

= 504

τRC (FODM3082, FODM3083)

Note:

This optoisolator should not be used to drive a load directly. It is intended to be a trigger device only.

1. The mercury wetted relay provides a high speed repeated

pulse to the D.U.T.

2. 100x scope probes are used, to allow high speeds and

voltages.

3. The worst-case condition for static dv/dt is established by

triggering the D.U.T. with a normal LED input current, then

removing the current. The variable RTEST allows the dv/dt

to be gradually increased until the D.U.T. continues to trigger

in response to the applied voltage pulse, even after the LED

current has been removed. The dv/dt is then decreased until

the D.U.T. stops triggering. tRC is measured at this point

and recorded.

Figure 9. Inverse-Parallel SCR Driver Circuit (240VAC)

VCC

Rin

240 VAC

SCR

360 Ω

R1 D1

SCR

R2 D2

LOAD

Suggested method of firing two, back-to-back

SCR’s, with a Fairchild triac driver. Diodes can

be 1N4001; resistors, R1 and R2, are optional

330 ohms.

Note:

This optoisolator should not be used to drive a load directly. It is intended to be a trigger device only.

FODM3062

FODM3063

FODM3082

FODM3083

FODM3062, FODM3063, FODM3082, FODM3083 Rev. 1.0.9 7

FODM3062, FODM3063, FODM3082, FODM3083 — 4-Pin Full Pitch Mini-Flat Package Zero-Cross Triac Driver Output Optocouplers

Figure 10. Hot-Line Switching Application Circuit

0.01

VCC

Rin 1

3240 VAC

HOT

NEUTRAL

360 Ω

*For highly inductive loads (power factor < 0.5), change this value to 360 ohms.

330

FODM3062

FODM3063

FODM3082

FODM3083 39*

LOAD

Typical circuit for use when hot line switching of 240VAC

is required. In this circuit the “hot” side of the line is

switched and the load connected to the cold or neutral

side. The load may be connected to either the neutral or

hot line.

Rin is calculated so that IF is equal to the rated IFT of the

part, 5mA for the FODM3063/83 and 10mA for the

FODM3062/82. The 39Ω resistor and 0.01µF capacitor are

for snubbing of the triac and may or may not be necessary

depending upon the particular triac and load used.

Determining the Power Rating of the Series Resistors Used in a Zero-Cross

Opto-TRIAC Driver Application

The following will present the calculations for

determining the power dissipation of the current

limiting resistors found in an opto-TRIAC driver

interface.

Figure 10 shows a typical circuit to drive a sensitive

gate four quadrant power TRIAC. This ﬁgure provides

typical resistor values for a zero line cross detecting

opto-TRIAC when operated from a mains voltage of

20V to 240V. The wattage rating for each resistor is

not given because their dissipation is dependent upon

characteristics of the power TRIAC being driven.

Recall that the opto-TRIAC is used to trigger a four

quadrant power TRIAC. Please note that these opto-

TRIACs are not recommended for driving

“snubberless” three quadrant power TRIACs.

Under normal operation, the opto-TRIAC will ﬁre when

the mains voltage is lower than the minimum inhibit

trigger voltage, and the LED is driven at a current

greater than the maximum LED trigger current. As an

example for the FODM3063, the LED trigger current

should be greater than 5mA, and the mains voltage is

less than 10V peak. The inhibit voltage has a typical

range of 10V minimum and 20V maximum. This

means that if a sufﬁcient LED current is ﬂowing when

the mains voltage is less than 10V, the device will ﬁre.

If a trigger appears between 10V and 20V, the device

may ﬁre. If the trigger occurs after the mains voltage

has reached 20Vpeak, the device will not ﬁre.

The power dissipated from resistors placed in series

with the opto-TRIAC and the gate of the power TRIAC

is much smaller than one would expect. These current

handling components only conduct current when the

mains voltage is less than the maximum inhibit

voltage. If the opto-TRIAC is triggered when the mains

voltage is greater than the inhibit voltage, only the

TRIAC leakage current will ﬂow. The power dissipation

in a 360

Ω

resistor shown in Figure 10 is the product of

the resistance (360

Ω

) times the square of the current

sum of main TRIAC’s gate current plus the current

ﬂowing gate to the MT2 resistor connection (330

Ω

This power calculation is further modiﬁed by the duty

factor of the duration for this current ﬂow. The duty

factor is the ratio of the turn-on time of the main TRIAC

to the sine of the single cycle time. Assuming a main

TRIAC turn-on time of 50µs and a 60Hz mains

voltage, the duty cycle is approximately 0.6%.

The opto-TRIAC only conducts current while triggering

the main TRIAC. Once the main TRIAC ﬁres, its on-

state voltage is typically lower than the on-state

sustaining voltage of the opto-TRIAC. Thus, once the

main TRIAC ﬁres, the opto-TRIAC is often shunted off.

This situation results in very low power dissipation for

both the 360

Ω

and 330

Ω

resistors, when driving a

traditional four quadrant power TRIAC.

If a three quadrant “snubberless” TRIAC is driven by

the opto-TRIAC, the calculations are different. When

the main power TRIAC is driving a high power factor

(resistive) load, it shuts off during the fourth quadrant.

FODM3062, FODM3063, FODM3082, FODM3083 Rev. 1.0.9 8

FODM3062, FODM3063, FODM3082, FODM3083 — 4-Pin Full Pitch Mini-Flat Package Zero-Cross Triac Driver Output Optocouplers

If sufﬁcient holding current is still ﬂowing through the

opto-TRIAC, the opto-TRIAC will turn-on and attempt

to carry the power TRIACs load. This situation typically

causes the opto-TRIAC to operate beyond its

maximum current rating, and product and resistor

failures typically result. For this reason, using an opto-

TRIAC to drive a three quadrant “snubberless” power

TRIAC is not recommended.

Power in the 360

Ω

resistor, when driving a sensitive

gate 4 quadrant power TRIAC:

= 20mA

= 1.5V

DF = 0.6%

P = (I

330

Ω

)

x 360

Ω

x DF

P = (20mA + 1.5

330

Ω

)

*x 360

Ω

x 0.6% = 1.3mW

A 1/4 watt resistor is more than adequate for both the

360

Ω

and 330

Ω

resistors.

The real power in the snubber resistor is based upon

the integral of the power transient present when the

load commutes. A fast commuting transient may allow

a peak current of 4A to 8A in the snubbing ﬁlter.

For best results, the capacitor should be a non-

polarized AC unit with a low ESR. The 39

Ω

series

resistor sets a time constant and limits the peak

current. For a resistive load with a power factor near

unity, the commutating transients will be small. This

results in a very small peak current given the 0.01µF

capacitor’s reactance. Normally, for factional horse-

power reactive loads, the resistor found in the snubber

circuit will have a power rating from 1/2W to 2W. The

resistor should be a low inductance type to adequately

ﬁlter the high frequency transients.

FODM3062, FODM3063, FODM3082, FODM3083 Rev. 1.0.9 9

FODM3062, FODM3063, FODM3082, FODM3083 — 4-Pin Full Pitch Mini-Flat Package Zero-Cross Triac Driver Output Optocouplers

Ordering Information

Marking Information

Option Description

No option Bulk (100 units/tube)

V VDE Approved

R2 Tape and Reel (2500 units)

R2V Tape and Reel (2500 units) and VDE Approved

Deﬁnitions

1Fairchild logo

2Device number

3 VDE mark (Note: Only appears on parts ordered with VDE

option – See order entry table)

4 One digit year code

5Two digit work week ranging from ‘01’ to ‘53’

6 Assembly package code

3063

XVR

FODM3062, FODM3063, FODM3082, FODM3083 Rev. 1.0.9 10

FODM3062, FODM3063, FODM3082, FODM3083 — 4-Pin Full Pitch Mini-Flat Package Zero-Cross Triac Driver Output Optocouplers

Tape and Reel Information

0PP

0B0

Reel Diameter

Devices Per Reel

Max. Component Rotation or Tilt

Cover Tape Thickness

Cover Tape Width

Pocket Hole Dia.

Pocket Dimension

Pocket Location

Sprocket Hole Location

Sprocket Hole Dia.

Sprocket Hole Pitch

Tape Thickness

Pocket Pitch

Tape Width

Description Symbol Dimensions

2.54 Pitch

330 mm (13")

12.00±0.4

7.30±0.20

20° max

1.55±0.20

2.30±0.20

0.065±0.02

9.20

1.75±0.20

8.00±0.20

2.00±0.20

5.50±0.20

4.75±0.20

1.55±0.20

4.00±0.20

0.35±0.02

2500

FODM3062, FODM3063, FODM3082, FODM3083 Rev. 1.0.9 11

FODM3062, FODM3063, FODM3082, FODM3083 — 4-Pin Full Pitch Mini-Flat Package Zero-Cross Triac Driver Output Optocouplers

Footprint Drawing for PCB Layout

Note:

All dimensions are in mm.

0.80

6.50

2.54

1.00

FODM3062, FODM3063, FODM3082, FODM3083 Rev. 1.0.9 12

FODM3062, FODM3063, FODM3082, FODM3083 — 4-Pin Full Pitch Mini-Flat Package Zero-Cross Triac Driver Output Optocouplers

Reﬂow Proﬁle

Proﬁle Feature Pb-Free Assembly Proﬁle

Temperature Min. (Tsmin) 150°C

Temperature Max. (Tsmax) 200°C

Time (t

) from (Tsmin to Tsmax) 60–120 seconds

Ramp-up Rate (t

to t

) 3°C/second max.

Liquidous Temperature (T

) 217°C

Time (t

) Maintained Above (T

) 60–150 seconds

Peak Body Package Temperature 260°C +0°C / –5°C

Time (t

) within 5°C of 260°C 30 seconds

Ramp-down Rate (T

to T

) 6°C/second max.

Time 25°C to Peak Temperature 8 minutes max.

Time (seconds)

Temperature (°C)

Time 25°C to Peak

260

240

220

200

180

160

140

120

100

Tsmax

Tsmin

120

Preheat Area

Max. Ramp-up Rate = 3°C/S

Max. Ramp-down Rate = 6°C/S

240 360

FODM3062, FODM3063, FODM3082, FODM3083 Rev. 1.0.9 13

TRADEMARKS

The following includes registered and unregistered trademarks and service marks, owned by Fairchild Semiconductor and/or its global subsidiaries,andisnot

intended to be an exhaustive list of all such trademarks.

AccuPower™

Auto-SPM™

Build it Now™

CorePLUS™

CorePOWER™

CROSSVOLT™

CTL™

Current Transfer Logic™

DEUXPEED®

Dual Cool™

EcoSPARK®

EfficientMax™

ESBC™

Fairchild®

Fairchild Semiconductor®

FACT Quiet Series™

FACT®

FAST®

FastvCore™

FETBench™

FlashWriter®*

FPS™

F-PFS™

FRFET®

Global Power ResourceSM

Green FPS™

Green FPS™e-Series™

Gmax™

GTO™

IntelliMAX™

ISOPLANAR™

MegaBuck™

MICROCOUPLER™

MicroFET™

MicroPak™

MicroPak2™

MillerDrive™

MotionMax™

Motion-SPM™

OptoHiT™

OPTOLOGIC®

OPTOPLANAR®

PDP SPM™

Power-SPM™

PowerTrench®

PowerXS™

Programmable Active Droop™

QFET®

QS™

Quiet Series™

RapidConfigure™

™

Saving our world, 1mW/W/kW at a time™

SignalWise™

SmartMax™

SMART START™

SPM®

STEALTH™

SuperFET™

SuperSOT™-3

SuperSOT™-6

SuperSOT™-8

SupreMOS®

SyncFET™

Sync-Lock™

®*

The Power Franchise®

TinyBoost™

TinyBuck™

TinyCalc™

TinyLogic®

TINYOPTO™

TinyPower™

TinyPWM™

TinyWire™

TriFault Detect™

TRUECURRENT™*

"SerDes™

UHC®

Ultra FRFET™

UniFET™

VCX™

VisualMax™

XS™

* Trademarks of System General Corporation, used under license by Fairchild Semiconductor.

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FAIRCHILD SEMICONDUCTOR RESERVES THE RIGHT TO MAKE CHANGES WITHOUT FURTHER NOTICE TO ANY PRODUCTS HEREIN TO IMPROVE

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are intended for surgical implant into the body or (b) support or

sustain life, and (c) whose failure to perform when properly used in

accordance with instructions for use provided in the labeling, can be

reasonably expected to result in a significant injury of the user.

2. A critical component in any component of a life support, device, or

system whose failure to perform can be reasonably expected to

cause the failure of the life support device or system, or to affect its

safety or effectiveness.

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PRODUCT STATUS DEFINITIONS

Definition of Terms

Datasheet

Identification

Product Status Definition

Advance Information Formative / In Design Datasheet contains the design specifications for product development. Specifications may change

in any manner without notice.

Preliminary First Production Datasheet contains preliminary data; supplementary data will be published at a later date. Fairchild

Semiconductor reserves the right to make changes at any time without notice to improve design.

No Identification Needed Full Production Datasheet contains final specifications. Fairchild Semiconductor reserves the right to make

changes at any time without notice to improve the design.

Obsolete Not In Production Datasheet contains specifications on a product that is discontinued by Fairchild Semiconductor.

The datasheet is for reference information only.

Rev. I49

FODM3062, FODM3063, FODM3082, FODM3083 — 4-Pin Full Pitch Mini-Flat Package Zero-Cross Triac Driver Output Optocouplers