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FODM30XX — 4-Pin Full Pitch Mini-Flat Package Zero-Cross Triac Driver Output Optocouplers

FODM30XX Rev. 1.2

May 2016

FODM3062, FODM3063, FODM3082, FODM3083

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

Triac Driver Output Optocouplers

Features

• Critical Rate of Rise of Off-Stage Voltage

- dv/dt of 600 V/µs Guaranteed

• Zero Voltage Crossing

• Peak Blocking Voltage

- 600 V (FODM306X)

- 800 V (FODM308X)

• Compact 4-Pin Surface Mount Package

- 2.4 mm Maximum Standoff Height

• Safety Regulatory Approvals:

- UL1577, 3,750 VACRMS for 1 Minute

- DIN-EN/IEC60747-5-5, 565 V Peak Working

Insulation Voltage

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 2.54 mm. 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.

Functional Schematic Package Outlines

MAIN TERM.

ANODE

CATHODE 3

4MAIN TERM.

ZERO

CROSSING

CIRCUIT

)LJXUH)XQFWLRQDO6FKHPDWLF

)LJXUH3DFNDJH2XWOLQH

FODM30XX Rev. 1.2 2

FODM30XX — 4-Pin Full Pitch Mini-Flat Package Zero-Cross Triac Driver Output Optocouplers

Safety and Insulation Ratings

As per DIN EN/IEC 60747-5-5, this optocoupler is suitable for “safe electrical insulation” only within the safety limit

data. Compliance with the safety ratings shall be ensured by means of protective circuits.

Note:

1. Safety limit values – maximum values allowed in the event of a failure.

Parameter Characteristics

Installation Classifications per DIN VDE

0110/1.89 Table 1, For Rated Mains Voltage

< 150 VRMS I–IV

< 300 VRMS I–III

Climatic Classification 40/100/21

Pollution Degree (DIN VDE 0110/1.89) 2

Comparative Tracking Index 175

Symbol Parameter Value Unit

VPR

Input-to-Output Test Voltage, Method A, VIORM x 1.6 = VPR,

Type and Sample Test with tm = 10 s, Partial Discharge < 5 pC 904 Vpeak

Input-to-Output Test Voltage, Method B, VIORM x 1.875 = VPR,

100% Production Test with tm = 1 s, Partial Discharge < 5 pC 1060 Vpeak

VIORM Maximum Working Insulation Voltage 565 Vpeak

VIOTM Highest Allowable Over-Voltage 6000 Vpeak

External Creepage  5mm

External Clearance  5mm

DTI Distance Through Insulation (Insulation Thickness)  0.4 mm

TSCase Temperature(1) 150 °C

IS,INPUT Input Current(1) 200 mA

PS,OUTPUT Output Power(1) 300 mW

RIO Insulation Resistance at TS, VIO = 500 V(1) > 109

FODM30XX Rev. 1.2 3

FODM30XX — 4-Pin Full Pitch Mini-Flat Package Zero-Cross Triac Driver Output Optocouplers

Absolute Maximum Ratings

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

ble above the recommended operating conditions and stressing the parts to these levels is not recommended. In addi-

tion, extended exposure to stresses above the recommended operating conditions may affect device reliability. The

absolute maximum ratings are stress ratings only. TA = 25°C unless otherwise specified.

Symbol Parameter Value Unit

TSTG Storage Temperature -55 to +150 °C

TOPR Operating Temperature -40 to +100 °C

TJJunction Temperature -40 to +125 °C

TSOL Lead Solder Temperature 260 for 10 sec °C

EMITTER

IF (avg) Continuous Forward Current 60 mA

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

VRReverse Input Voltage 6 V

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

DETECTOR

IT(RMS) On-State RMS Current 70 mA

VDRM Off-State Output Terminal Voltage FODM3062/FODM3063 600 V

FODM3082/FODM3083 800 V

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

FODM30XX Rev. 1.2 4

FODM30XX — 4-Pin Full Pitch Mini-Flat Package Zero-Cross Triac Driver Output Optocouplers

Electrical Characteristics

TA = 25°C unless otherwise specified.

Individual Component Characteristic s

Transfer Characteristics

Zero Crossing Characteristics

Isolation Characteristics

Notes:

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

3. This is static dv/dt. See Figure 10 for test circuit. Commutating dv/dt is function of the load-driving thyristor(s) only.

4. All devices are guaranteed to trigger at an IF value less than or equal to max IFT

. Therefore, recommended

operating IF lies between max IFT (10mA for FODM3062/82, 5mA for FODM3063/83) and absolute max IF (60 mA).

5. Steady state isolation voltage, VISO, 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 Device Min. Typ. Max. Unit

EMITTER

VFInput Forward Voltage IF = 30 mA All 1.50 V

IRReverse Leakage Current VR = 6 V All 100 μA

DETECTOR

IDRM

Peak Blocking Current Either

Direction Rated VDRM, IF = 0(2) All 500 nA

dv/dt Critical Rate of Rise of

Off-State Voltage IF = 0 (Figure 10)(3) All 600 V/μs

Symbol Parameter Test Conditions Device Min. Typ. Max. Unit

IFT LED Trigger Current Main Terminal

Voltage = 3 V(4)

FODM3062,

FODM3082 10

FODM3063,

FODM3083 5

Holding Current, Either Direc-

tion All 300 µA

VTM

Peak On-State Voltage,

Either Direction

IF = Rated IFT

ITM = 100 mA peak All 3 V

Symbol Parameter Test Conditions Device Min. Typ. Max. Unit

VIH

Inhibit Voltage,

MT1-MT2 Voltage

above which device

will not trigger

IFT = Rated IFT

All 20 V

IDRM2 Leakage in Inhibit State

IFT = Rated IFT

Rated VDRM,

Off-State

All 2 mA

Symbol Parameter Test Conditions Device Min. Typ. Max. Unit

VISO Steady State Isolation

Voltage(5)

1 Minute,

R.H. = 40% to 60% All 3,750 VACRMS

FODM30XX Rev. 1.2 5

FODM30XX — 4-Pin Full Pitch Mini-Flat Package Zero-Cross Triac Driver Output Optocouplers

Typical Performance Characteristics

IF - FORWARD CURRENT (mA)

Fig.  LED Forward Voltage vs. Forward Current

1 100

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

-40 -20 02040 60 80 

TA - AMBIENT TEMPERATURE (°C)

Fig.  Leakage Current vs. Ambient Temperature

100

IDRM - LEAKAGE CURRENT (nA)

0.1

100

1000

VDRM = 600V

02040 06

TA - AMBIENT TEMPERATURE (°C)

Fig.  Holding Current vs. Ambient Temperature

-40 -20 100

- HOLDING CURRENT (NORMALIZED)

0.1

1.0

NORMALIZED TO TA = 25°C

0204060

TA - AMBIENT TEMPERATURE (°C)

Fig.  Trigger Current vs. Ambient Temperature

-40 -20 80

IFT - TRIGGER CURRENT (NORMALIZED)

0.8

0.6

0.8

1.0

1.2

1.4

1.6

VTM = 3V

NORMALIZED TO TA = 25°C

100

FODM30XX Rev. 1.2 6

FODM30XX — 4-Pin Full Pitch Mini-Flat Package Zero-Cross Triac Driver Output Optocouplers

Typical Performance Characteristics (Continued)

-1012

VTM - ON-STATE VOLTAGE (V)

Fig.  On-State Characteristics

-4 -3 -2 3 4

ITM - ON-STATE CURRENT (mA)

-200

-400

-600

-800

200

400

600

800

TA = 25°C

Fig.  Off-State Output Terminal Voltage vs. Ambient Temperature

PWIN - LED TRIGGER PULSE WIDTH (°C)

Fig.  LED Current Required to Trigger vs. LED Pulse Width

1001

IFT - LED TRIGGER CURRENT (NORMALIZED)

NORMALIZED TO

PWIN>

> 100μs

NORMALIZED TO T

A = 25°C

02040 06

TA - AMBIENT TEMPERATURE (°C)

VDRM

- OFF-STATE OUTPUT TERMINAL VOLTAGE

(NORMALIZED)

1.3

1.2

1.1

1.0

0.9

0.8

0.7

0.6

1.4

-40 -20

80 100

TA = 25°C

FODM30XX Rev. 1.2 7

FODM30XX — 4-Pin Full Pitch Mini-Flat Package Zero-Cross Triac Driver Output Optocouplers

Typical Application Information

Figure . Static dv/dt Test Circuit

800V (FODM3082)Vdc

(FODM3083)

600V (FODM3062)

(FODM3063)

R = 10 kΩ

CTEST

X100

SCOPE

PROBE

PULSE

INPUT MERCURY

WETTED

RELAY

78V (FODM3062, FODM3063)

504V (FODM3082, FODM3083)

0 VOLTS

APPLIED VOLTAGE

WAVEFORM

dv/dt = 0.63 Vmax

RTEST

D.D.UU..TT..

τRC

Vmax == 800V (FODM3082, FODM3083)

=600V (FODM3062, FODM3063)

= 378

τRC (FODM3062, FODM3063)

= 504

τRC (FODM3082, FODM3083)

τRC

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 . Inverse-Parallel SCR Driver Circuit (240VAC)

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

FODM30XX Rev. 1.2 8

FODM30XX — 4-Pin Full Pitch Mini-Flat Package Zero-Cross Triac Driver Output Optocouplers

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

TRIAC Driver Application

Figure 1. Hot-Line Switching Application Circuit

0.01ȝ)

VCC

Rin 1

3240 VAC

HOT

NEUTRAL

360 Ω

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

FODM3062

FODM3063

FODM3082

FODM3083 39

LOAD

Typical circuit for use when hot line switching of 240VAC

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

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

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

necessary depending upon the particular triac and load

used.

The following will present the calculations for

determining the power dissipation of the current

limiting resistors found in an opto-TRIAC driver

interface.

Figure 1 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

20V to 240V. 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 10V peak. The inhibit voltage has a typical

range of 10V minimum and 20V maximum. This

means that if a sufﬁcient LED current is ﬂowing when

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

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

may ﬁre. If the trigger occurs after the mains voltage

has reached 20Vpeak, 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 1 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 50μs

and a 60Hz 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.

30 Ω

FODM30XX Rev. 1.2 9

FODM30XX — 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:

IGT = 20mA

VGT = 1.5V

DF = 0.6%

P = (IGT +VGT / 330Ω)2 x 360Ω x DF

P = (20mA + 1.5 / 330Ω)2 *x 360Ω x 0.6% = 1.3mW

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 4A to 8A in the snubbing ﬁlter.For

best results, the capacitor should be a non-polarized

AC unit with a low ESR. The 39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 0.01μFcapacitor’s

reactance. Normally, for factional horse-power reactive

loads, the resistor found in the snubbercircuit will

have a power rating from 1/2W to 2W. Theresistor

should be a low inductance type to adequatelyﬁlter

the high frequency transients.

FODM30XX Rev. 1.2 10

FODM30XX — 4-Pin Full Pitch Mini-Flat Package Zero-Cross Triac Driver Output Optocouplers

Reflow Profile

Proﬁle Freature Pb-Free Assembly Proﬁle

Temperature Min. (Tsmin) 150°C

Temperature Max. (Tsmax) 200°C

Time (tS) from (Tsmin to Tsmax) 60–120 seconds

Ramp-up Rate (tL to tP) 3°C/second max.

Liquidous Temperature (TL) 217°C

Time (tL) Maintained Above (TL) 60–150 seconds

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

Time (tP) within 5°C of 260°C 30 seconds

Ramp-down Rate (TP to TL) 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

Tsm a x

Tsm i n

120

Preheat Area

Max. Ramp-up Rate = 3°C/S

Max. Ramp-down Rate = 6°C/S

240 360

FODM30XX Rev. 1.2 11

FODM30XX — 4-Pin Full Pitch Mini-Flat Package Zero-Cross Triac Driver Output Optocouplers

Ordering Information

Note:

The product orderable part number system listed in this table also applies to the FODM3062, FODM3082 and

FODM3083 products.

Marking Information

Figure 13. Top Mark

Table 1. Top Mark Definitions

Part Number Package Packing Method

FODM3063 Full Pitch Mini-Flat 4-Pin Tube (100 units)

FODM3063R2 Full Pitch Mini-Flat 4-Pin Tape and Reel (2500 Units)

FODM3063V Full Pitch Mini-Flat 4-Pin, DIN EN/IEC60747-5-5 Option Tube (100 Units)

FODM3063R2V Full Pitch Mini-Flat 4-Pin, DIN EN/IEC60747-5-5 Option Tape and Reel (2500 Units)

1 Fairchild Logo

2 Device Number

3 DIN EN/IEC60747-5-5 Option (only appears on component ordered with this option)

4 One-Digit Year Code, e.g., “6”

5 Digit Work Week, Ranging from “01” to “53”

6 Assembly Package Code

3063

XV R

FODM30XX Rev. 1.2 12

FODM30XX — 4-Pin Full Pitch Mini-Flat Package Zero-Cross Triac Driver Output Optocouplers

Tape Specifications

0PP

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

FODM30XX Rev. 1.2 13

FODM30XX — 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

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Buyer is responsible for its products and applications using ON Semiconductor products, including compliance with all laws, regulations and safety requirements or standards,

regardless of any support or applications information provided by ON Semiconductor. “Typical” parameters which may be provided in ON Semiconductor data sheets and/or

specifications can and do vary in different applications and actual performance may vary over time. All operating parameters, including “Typicals” must be validated for each customer

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Fax: 303−675−2176 or 800−344−3867 Toll Free USA/Canada

Email: orderlit@onsemi.com

ON Semiconductor Website: www.onsemi.com

Order Literature: http://www.onsemi.com/orderlit

For additional information, please contact your local

Sales Representative