ADP1046DC1-EVALZ Analog Devices, ADP1046DC1-EVALZ Datasheet - Page 85

ADP1046DC1-EVALZ

Manufacturer Part Number

ADP1046DC1-EVALZ

Description

Daughter Cards & OEM Boards ADP1046 Daughter Card

Manufacturer

Analog Devices

Series

ADP1046r

Datasheet

1.ADP1046DC1-EVALZ.pdf (92 pages)

Specifications of ADP1046DC1-EVALZ

Rohs

yes

Product

Daughter Cards

Description/function

100 kHz daughter board

Interface Type

I2C

Maximum Operating Temperature

+ 125 C

Minimum Operating Temperature

- 40 C

Operating Supply Voltage

3.3 V

Factory Pack Quantity

For Use With

ADP1046

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Data Sheet

RESONANT MODE OPERATION

The

Resonant converters are an alternative to traditional fixed

frequency converters. They offer high switching frequency,

small size, and high efficiency. Figure 58 illustrates a widely

used series resonant converter.

RESONANT MODE ENABLE

To enable the

verter, Register 0x40 must be set to a value of 0x3F. In resonant

mode, the PWM outputs have a fixed duty cycle with variable

frequency.

PWM TIMING IN RESONANT MODE

With variable frequency control, OUTA and OUTB can only be

high during the first half of the switching cycle (t

OUTC and OUTD can only be high during the second half of

the switching cycle (t

frequency resolution of the control law is in steps of 10 ns.

PWM1 (OUTA)

PWM2 (OUTB)

PWM3 (OUTC)

PWM4 (OUTD)

ADP1046

Figure 59. OUTA, OUTB, OUTC, and OUTD PWM Timing Diagram

ADP1046

supports control of a resonant converter.

Δt

Figure 58. Series Resonant Converter

to t

PERIOD

to control a resonant switching con-

in Resonant Mode

Δt

), as shown in Figure 59. The

Δt

SR2

SR1

PERIOD

to t

), whereas

Rev. B | Page 85 of 92

SYNCHRONOUS RECTIFICATION IN RESONANT

MODE

Control of the synchronous rectifiers in a resonant controller is

a complicated issue. The

used to control the SR signals. In resonant mode operation, the

SR1 output is driven by the rising edge of the ACSNS comparator,

and the SR2 output is driven by the falling edge of the comparator,

as shown in Figure 60.

Following is an example of how the

series resonant topology and also achieve control of the synchro-

nous rectifiers. The V

used to control the SR signals. The ACSNS pin is connected to

the divided-down SR2 V

information for both synchronous rectifiers (see Figure 61).

After the timing information is obtained, SR1 is driven by the

rising edge of the ACSNS comparator, and SR2 is driven by the

falling edge of the comparator, as shown in Figure 60. In this

way, it is possible to achieve synchronous rectification. Turn-on

and turn-off delays can be programmed for the SR1 and SR2

signals individually.

This example is not the only way to control the SR signals. If the

user has another method to control the SR signals, this method

can be used to connect to the ACSNS input instead of the V

voltage of SR2.

When the

recommended that SR soft start be disabled during soft start of

the device (set Register 0x0F[7] = 1).

SYNC RECT 1 (SR1)

SYNC RECT 2 (SR2)

Figure 60. SR1 and SR2 PWM Timing Diagram in Resonant Mode

Figure 61. Resonant Synchronous Rectifier Control Circuit

ADP1046

ACSNS

(SR2)

Δt

is used to control a resonant converter, it is

voltage of SR2 (see Figure 60) can be

ADP1046

voltage. This provides the timing

Δt

SR2

SR1

Δt

ACSNS comparator can be

ADP1046

Δt

can be used in a

ADP1046

ACSNS

ADP1046DC1-EVALZ Analog Devices, ADP1046DC1-EVALZ Datasheet - Page 85

ADP1046DC1-EVALZ

Specifications of ADP1046DC1-EVALZ

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