LTC3876_15 Datasheet, PDF(20/48 Page) Linear Technology – Dual DC/DC Controller for DDR Power with Differential VDDQ Sensing and 50mA VTT Reference

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LTC3876_15 Datasheet, PDF (20/48 Pages) Linear Technology – Dual DC/DC Controller for DDR Power with Differential VDDQ Sensing and 50mA VTT Reference

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LTC3876

APPLICATIONS INFORMATION

Inductor Core Selection

Once the value for L is known, the type of inductor must

be selected. The two basic types are iron powder and fer-

rite. The iron powder types have a soft saturation curve

which means they do not saturate hard like ferrites do.

However, iron powder type inductors have higher core

losses. Ferrite designs have very low core loss and are

preferred at high switching frequencies, so design goals

can concentrate on copper loss and preventing saturation.

Core loss is independent of core size for a fixed inductor

value, but it is very dependent on inductance selected. As

inductance increases, core losses go down. Unfortunately,

increased inductance requires more turns of wire and

therefore copper losses will increase.

Ferrite core material saturates hard, which means that in-

ductance collapses abruptly when the peak design current

is exceeded. This results an abrupt increase in inductor

ripple current and consequent output voltage ripple. Do

not allow the core to saturate!

A variety of inductors designed for high current, low volt-

age applications are available from manufacturers such as

Sumida, Panasonic, Coiltronics, Coilcraft, Toko, Vishay,

Pulse and WÃ¼rth.

Current Sense Pins

Inductor current is sensed through voltage between

SENSE+ and SENSEâ pins, the inputs of the internal current

comparators. The input voltage range of the SENSE pins is

â0.5V to 5.5V. Care must be taken not to float these pins

during normal operation. The SENSE+ pins are quasi-high

impedance inputs. There is no bias current into a SENSE+

pin when its corresponding channelâs SENSEâ pin ramps

up from below 1.1V and stays below 1.4V. But there is a

small (~1Î¼A) current flowing into a SENSE+ pin when its

corresponding SENSEâ pin ramps down from 1.4V and

stays above 1.1V. Such currents also exist on SENSEâ pins.

But in addition, each SENSEâ pin has an internal 500k

resistor to SGND. The resulted current (VOUT/500k) will

dominate the total current flowing into the SENSEâ pins.

SENSE+ and SENSEâ pin currents have to be taken into

account when designing either RSENSE or DCR inductor

current sensing.

Current Limit Programming

The current sense comparatorsâ maximum trip voltage

between SENSE+ and SENSEâ (or âsense voltageâ), when

ITH is clamped at its maximum, is set by the voltage ap-

plied to the VRNG pin and is given by:

VSENSE(MAX) = 0.05VRNG

The valley current mode control loop does not allow the

inductor current valley to exceed 0.05VRNG. In practice, one

should allow sufficient margin, to account for tolerance of

the parts and external component values. Note that ITH is

close to 2.4V for channel 1 and 2.2V for channel 2 when

in positive current limit.

An external resistive divider from INTVCC can be used to set

the voltage on a VRNG pin between 0.6V and 2V, resulting

in a maximum sense voltage between 30mV and 100mV.

Such wide voltage range allows for variety of applications.

The VRNG pin can also be tied to either SGND or INTVCC

to force internal defaults. When VRNG is tied to SGND, the

device has an equivalent VRNG of 0.6V. When the VRNG pin

is tied to INTVCC, the device has an equivalent VRNG of 2V.

RSENSE Inductor Current Sensing

The LTC3876 can be configured to sense the inductor

currents through either low value series current sensing

resistors (RSENSE) or inductor DC resistance (DCR). The

choice between the two current sensing schemes is largely

a design trade-off between cost, power consumption and

accuracy. DCR sensing is becoming popular because it

saves expensive current sensing resistors and is more

power efficient, especially in high current applications.

However, current sensing resistors provide the most ac-

curate current limits for the controller.

A typical RSENSE inductor current sensing scheme is shown

in Figure 3a. The filter components (RF, CF) need to be

placed close to the IC. The positive and negative sense

traces need to be routed as a differential pair close to-

gether and (4-wire) Kelvin connected underneath the sense

resistor, as shown in Figure 3b. Sensing current elsewhere

can effectively add parasitic inductance to the current sense

element, degrading the information at the sense terminals

and making the programmed current limit unpredictable.

3876f

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