ISL1904FAZ-T Intersil, ISL1904FAZ-T Datasheet - Page 15

ISL1904FAZ-T

Manufacturer Part Number

ISL1904FAZ-T

Description

LED Lighting Drivers High Power LED Controllers, T&R

Manufacturer

Intersil

Datasheet

1.ISL1904FAZ-T7A.pdf (21 pages)

Specifications of ISL1904FAZ-T

Input Voltage

9 VDC to 20 VDC

Operating Frequency

349 Hz

Maximum Operating Temperature

+ 125 C

Mounting Style

SMD/SMT

Package / Case

QSOP-16

Minimum Operating Temperature

- 40 C

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The first calculation required is to determine the required

secondary inductance shown by Equation 2.

The turns ratio N

Knowing the secondary inductance and the turns ratio, the

primary inductance can be calculated by using Equation 4.

With this information, the lowest switching frequency, which

occurs at maximum load and at the peak instantaneous input

voltage at the minimum RMS voltage, can be determined. By

selecting the maximum duty cycle and a typical average

frequency, the ON-time is already determined by Equation 5.

The primary peak current at the end of the ON-time is shown in

Equation 6:

The peak secondary current is the peak primary current divided

by the transformer turns ratio shown in Equation 7.

η =

Dmin =

Ls =

Lp =

Nsp =

Ip(peak) =

p peak

s peak

min(avg)

ON(MAX)

OFF

delay

mINrms

maxINrms

(

max

------------ -

------------------------------------------- -

--------------------------------------------------- -

η V

------------------------ -

)

typ avg

min avg

⋅

(

max

= Maximum RMS input voltage

1 D

(

--------------------------------------- -

--------------------- -

mINrms

p peak

⋅

–

rms

(

Minimum RMS input voltage

Efficiency

Typical frequency when V

Maximum typical duty cycle desired

Minimum typical duty cycle

ON-time of the power FET controlled by OUT

OFF-time duration required for CrCM operation

Secondary inductance

Primary inductance

Transformer turns ratio, Ns/Np

Peak primary current within a switching cycle

User adjustable delay before the next switching cycle

begins

1 D

typ(avg)

)

IN(rms)

)

⋅

max

–

TABLE 1. OSCILLATOR DEFINITIONS

2 I

⋅

)

⋅

max

⋅

2 t

is calculated next in Equation 3.

)

⋅

x D

max

)

max

(instantaneous) = minimum

(EQ. 2)

(EQ. 3)

(EQ. 4)

(EQ. 5)

(EQ. 6)

(EQ. 7)

ISL1904

And the OFF-time is shown in Equation 8:

The lowest switching frequency is the reciprocal of the sum of the

ON-time, the OFF-time, and the delay time is shown in

Equation 9.

The delay time can be approximated if the equivalent

drain-source capacitance (C

This value should also include any parasitic capacitance on the

drain node. These parameters may not be known during the early

stages of the design, but are typically on the order of 300ns to

500ns.

If the lowest frequency does not meet the requirements, then

iterative calculations may be required.

The highest frequency is determined by the shortest ON-time

summed with t

minimum load, and occurs at or near the AC zero crossing when

the primary (and secondary) current is zero. The minimum

non-zero ON-time the ISL1904 can produce is ~100ns,

suggesting an operating frequency above 1MHz. In any event the

maximum frequency clamp would limit the frequency to about

1MHz. Once the primary and secondary inductances are known,

the general formulae to calculate the ON-time and OFF-time at

an equivalent DC input voltage are shown by Equations 11 and

12:

It is clear from the equations there is a linear relationship

between load current and frequency. At some light load the

frequency will be limited by the maximum frequency clamp.

There is an inverse relationship between the input voltage and

frequency and its effect is restricted by the typical input voltage

range.

It should be noted, however, that the above equations assume

full conduction angle of the AC mains. When conduction angle

modulating dimmers are used to block a portion of each AC

half-cycle, the switching currents remain essentially unchanged

during the conduction portion of the AC half-cycle as the

conduction angle is reduced. The conduction angle is reduced,

not the amplitude of the waveform envelope. The result being the

steady state frequency behavior will not vary much as the

conduction angle is reduced.

OFF

min

delay

OFF

≈

2 L

------------------------------------- -

--------------------------------------------------- -

------------------------------- -

-----------------------------------------------------------------

2 L

---------------------- -

⋅

INrms

s peak

⋅

(

⋅

OFF

⋅

delay

(

⋅

⎛

⎜

⎝

oss

)

. The shortest ON-time occurs at high line and

delay

⋅

-------------------------------- -

⎛

⎜

⎝

⋅

other

-------------------------------- -

INrms

oss

⋅

)

⋅

) of the primary switch is known.

INrms

⎞

⎟

⎠

⋅

⎞

⎟

⎠

September 20, 2012

FN8286.1

(EQ. 10)

(EQ. 11)

(EQ. 12)

(EQ. 8)

(EQ. 9)

ISL1904FAZ-T Intersil, ISL1904FAZ-T Datasheet - Page 15

ISL1904FAZ-T

Specifications of ISL1904FAZ-T

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