LTC3722-2_15 Datasheet, PDF(13/28 Page) Linear Technology – Synchronous Dual Mode Phase Modulated Full Bridge Controllers

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LTC3722-2_15 Datasheet, PDF (13/28 Pages) Linear Technology – Synchronous Dual Mode Phase Modulated Full Bridge Controllers

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LTC3722-1/LTC3722-2

OPERATION

occur, independent of load current as long as energy in

the transformerâs magnetizing and leakage inductance is

greater than the capacitive energy. That is, 1/2 â¢ (LM + LI)

â¢ IM2 > 1/2 â¢ 2 â¢ COSS â¢ VIN2 â the worst case occurs

when the load current is zero. This condition is usually

easy to meet. The magnetizing current is virtually constant

during this transition because the magnetizing inductance

has positive voltage applied across it throughout the low

to high transition. Since the leg is actively driven by this

current source, it is called the active or linear transition.

When the voltage on the active leg has risen to VIN,

MOSFET MC is switched on by the ZVS circuitry. The

primary current now flows through the two high side

MOSFETs (MA and MC). The transformerâs secondary

windings are electrically shorted at this time since both

ME and MF are âONâ. As long as positive current flows

in LO1 and LO2, the transformer primary (magnetizing)

inductance is also shorted through normal transformer

action. MA and MF turn off at the end of State 2.

State 3 (Passive Transition)

MA turns off when the oscillator timing period ends, i.e.,

the clock pulse toggles the internal flip-flop. At the instant

MA turns off, the voltage on the MA/MB junction begins to

decay towards the lower supply (GND). The energy available

to drive this transition is limited to the primary leakage

inductance and added commutating inductance which

have (IMAG + IOUT/2N) flowing through them initially. The

magnetizing and output inductors do not contribute any

energy because they are effectively shorted as mentioned

previously, significantly reducing the available energy. This

is the major difference between the active and passive

transitions. If the energy stored in the leakage and com-

mutating inductance is greater than the capacitive energy,

the transition will be completed successfully. During the

transition, an increasing reverse voltage is applied to the

leakage and commutating inductances, helping the overall

primary current to decay. The inductive energy is thus

resonantly transferred to the capacitive elements, hence,

the term passive or resonant transition. Assuming there

is sufficient inductive energy to propel the bridge leg to

GND, the time required will be approximately equal to:

Ï LC

When the voltage on the passive leg nears GND, MOSFET

MB is commanded âONâ by the ZVS circuitry. Current

continues to increase in the leakage and external series

inductance which is opposite in polarity to the reflected

output inductor current. When this current is equal in

magnitude to the reflected output current, the primary

current reverses direction, the opposite secondary winding

becomes forward biased and a new power pulse is initi-

ated. The time required for the current reversal reduces

the effective maximum duty cycle and must be considered

when computing the power transformer turns ratio. If

ZVS is required over the entire range of loads, a small

commutating inductor is added in series with the primary

to aid with the passive leg transition, since the leakage

inductance alone is usually not sufficient and predictable

enough to guarantee ZVS over the full load range.

State 4 (Power Pulse 2)

During power pulse 2, current builds up in the primary

winding in the opposite direction as power pulse 1. The

primary current consists of reflected output inductor cur-

rent and current due to the primary magnetizing inductance.

At the end of State 4, MOSFET MC turns off and an active

transition, essentially similar to State 2 but opposite in

direction (high to low), takes place.

Zero Voltage Switching (ZVS)

A lossless switching transition requires that the respective

full bridge MOSFETs be switched to the âONâ state at the

exact instant their drain-to-source voltage is zero. Delaying

the turn-on results in lower efficiency due to circulating cur-

rent flowing in the body diode of the primary side MOSFET

rather than its low resistance channel. Premature turn-on

produces hard switching of the MOSFETs, increasing noise

and power dissipation.

LTC3722-1/LTC3722-2 Adaptive Delay Circuitry

The LTC3722-1/LTC3722-2 monitors both the input supply

and instantaneous bridge leg voltages, and commands

a switching transition when the expected zero voltage

condition is reached. DirectSense technology provides

optimal turn-on delay timing, regardless of input voltage,

output load, or component tolerances. The DirectSense

technique requires only a simple voltage divider sense

372212fb

For more information www.linear.com/LTC3722

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