RDK-239 Power Integrations, Inc., RDK-239 Datasheet - Page 16

RDK-239

Manufacturer Part Number

RDK-239

Description

Specifications: Family: Eval Boards - DC/DC & AC/DC (Off-Line) SMPS ; Series: HiperLCS™ ; Main Purpose: DC/DC, Step Down ; Outputs and Type: 1, Isolated ; Power - Output: 150W ; Voltage - Output: 24V ; Current - Output: 6.25A ; Voltage - Input:

Manufacturer

Power Integrations, Inc.

Datasheet

1.RDK-239.pdf (26 pages)

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It should be noted that the 4.7 nF decoupling capacitor, C

(see Figure 19), in conjunction with the 2.5 kW input resistance

presented by the FEEDBACK pin, form a pole in the LLC

transfer function. This can add significant phase lag to the

feedback loop. A typical value for a 250 kHz design with a

3 kHz crossover frequency is 4.7 nF. To prevent loop instability,

the value of the 4.7 nF capacitor should not be increased

arbitrarily. At the other extreme, insufficient FEEDBACK pin

bypass capacitance or poor layout may cause duty cycle

asymmetry.

Start-Up and Auto-Restart

At start-up and during the off-state of the auto-restart cycle, the

FEEDBACK pin is internally pulled up to the VREF pin. This

keeps the output MOSFETs off and discharges the soft-start

capacitor, in preparation for soft-start.

At start-up, this state remains for 1024 clock cycles at frequency

is triggered while the VCC remains above its UVLO threshold, this

state remains for 131,072 clock cycles.

After 1024 or 131,072 cycles (as the case may be), the HiperLCS

turns off the internal pull-up transistor, the soft-start capacitor

begins to charge, the output MOSFETs switch at f

the FEEDBACK pin diminishes, the frequency begins to drop,

and the PSU output rises.

For example, for f

power-up is 1.3 ms. If IS, or the OV/UV pin are tripped, auto-

restart is invoked, with a restart delay of 164 ms.

The FEEDBACK pin has a current limit equal to the current

flowing into the DT/BF pin. This limits the maximum current that

charges the soft-start capacitor at start-up. If R

than that which allows the FEEDBACK pin current to match the

DT/BF pin current at start-up, an additional delay is introduced.

commence when the FEEDBACK pin voltage drops below 2.0 V.

Thus the designer can add an additional start-up delay if desired.

As the soft-start capacitor continues to charge, the current

through R

switching frequency. The output voltage climbs; and when the

feedback loop closes, the optocoupler conducts and starts

controlling the switching frequency thus the output voltage.

Remote-Off

Remote-off can be invoked by pulling down the OV/UV pin to

ground, or by pulling up the IS pin to >0.9 V. Both will invoke a

131,072 cycle restart cycle. VCC can also be pulled down to shut

the device off, but when it is pulled up, the FEEDBACK pin is

pulled up to the VREF pin to discharge the soft-start capacitor for

only 1024 f

must ensure that the time the VCC is pulled down, plus 1024

cycles, is sufficient to discharge the soft-start capacitor, or if not,

that the resulting lower starting frequency is high enough so as

not to cause excessive primary currents that may cause the

over-current protection to trip.

Rev. B 062011

MAX

START

. During the off-state of auto-restart, or if the OV/UV or IS pin

will charge at the current limit, and switching will only

START

MAX

LCS700-708

clock cycles. If this scheme is used, the designer

and thus the FEEDBACK pin decreases, reducing

MAX

= 800 kHz, the start-up delay after VCC

START

MAX

is smaller

, current in

Figure 22. Typical Start-up Waveform. Observe Initial Current Spike ‘A’ to Ensure

IS Pin

The IS pin has 2 thresholds: nominally 0.5 V and 0.9 V. The IS

pin can tolerate small negative voltages and currents, and thus

does not need a peak detector or rectifier circuit. The pin has a

reverse-biased diode to ground equivalent circuit, and can

tolerate a maximum negative current of 5 mA. The primary

current is sampled by a primary, B- referenced current sense

resistor, or by a capacitor current divider + current sense resistor

combination circuit. In order to limit the negative current to 5 mA,

a current limiting resistor between the sense resistor and the IS

pin is necessary, with a minimum value of 220 W. Using the

minimum value maximizes the IS pin bypass capacitor value

and thus pin noise rejection, for a given RC pole frequency.

The IS pin will invoke a restart if it sees 7 consecutive pulses

>0.5 V. It will also invoke a restart if a single pulse exceeds 0.9 V.

The minimum pulse detection time is nominally 30 ns – i.e. the

pulses must be higher than the threshold voltage for >30 ns.

The “capacitive divider” circuit in Figure 23 reduces power

dissipation and improves efficiency over a simple current sense

resistor circuit. The two capacitors, main resonant capacitor

C11, and sense capacitor C12, form a current divider. The

portion of the primary current routed through C12 is

Consequently, the voltage at the IS pin is equal to

where I

the transformer primary. The current in the sense capacitor

passes through sense resistor R11. Resistor R11 is the main

means for tuning current limit. The signal on R11, an AC

voltage, passes through low-pass filter R12 and C7, to the IS

pin. Note that R11 is returned to the GROUND pin and not to

SOURCE pin.

-10

-2

-4

-6

-8

is the primary current flowing from the HB pin through

it is Below the 1-Cycle Current Limit. A Higher f

the Soft-Start Capacitor so that the Peak of ‘B’ is just Below the Peak

Current at V

0.5

BROWNOUT

1.5

at Full Load.

Time (ms)

2.5

Primary Current

Output Voltage

3.5

www.powerint.com

MAX

PI-6471-052411

Reduces it. Size

4.5

RDK-239 Power Integrations, Inc., RDK-239 Datasheet - Page 16

RDK-239

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