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LTC3883/LTC3883-1

3883fa

For more information www.linear.com/LTC3883

APPLICATIONS INFORMATION

the accuracy in calculating θ

, the two load currents should

be chosen around I

= 10% and I

= 90% of the current

range of the system.

The inductor thermal time constant τ models the first order

thermal response of the inductor and allows accurate DCR

compensation during load transients. During a transition

from low-to-high load current, the inductor resistance

increases due to the self-heating. If we apply a single load

step from the low current I

to the higher current I

, the

voltage across the inductor will change instantaneously

from I

R1 to I

R1 and then slowly approach I

R2. Here R1

is the steady-state resistance at the given temperature and

load current I

, and R2 is the slightly higher DC resistance

at I

, due to the inductor self-heating. Note that the electri-

cal time constant τ

= L/R is several orders of magnitude

shorter than the thermal one, and “instantaneous” is rela-

tive to

the thermal time constant. The two settled regions

give

us the data sets (I

, T1, R1, P1) and (I

, T2, R2, P2)

and the 2-point calibration technique (1.3-1.4) is used to

extract the steady-state parameters θ

and R0 (given a

previously characterized average a). The relative current

error calculated using the steady-state expression (1.2)

will peak immediately after the load step, and then decay

to zero with the inductor thermal time constant τ.

∆

( )

= aθ

V2I

– V1I

( )

– t/ τ

The time constant τ is calculated from the slope of the

best-fit line y = ln(∆I/I) = a1 + a2t:

τ = –

In summary, a single load current step is all that is needed

to calibrate the DCR current measurement. The stable por-

tions of

the

response give us the thermal resistance θ

and

nominal DC resistance R0, and the settling characteristic

is used to measure the inductor thermal time constant τ.

To get the best performance, the temperature sensor has

to be as close as possible to the inductor and away from

other significant heat sources. For example in Figure 30,

the bipolar sense transistor is close to the inductor and

away from the switcher. Connecting the collector of the

PNP to the local power ground plane assures good thermal

contact to the inductor, while the base and emitter should

be routed to the LTC3883 separately, and the base con

nected to the signal ground close to LTC3883.

TpowerPlay: A

N INTERACTIVE GUI FOR DIGITAL

POWER

LTpowerPlay is a powerful Windows-based development

environment that supports Linear Technology digital

power ICs including the LTC3883. The software supports

a variety of different tasks. LTpowerPlay can be used to

evaluate Linear Technology ICs by connecting to a demo

board or the user application. LTpowerPlay can also be

used in an offline mode (with no

hardware present) in

order to build multiple IC configuration files that can be

saved and re-loaded at a later time. LTpowerPlay provides

unprecedented diagnostic and debug features. It becomes

a valuable diagnostic tool during board bring-up to pro

gram or

tweak the power system or to diagnose power

issues

when bring up rails. LTpowerPlay utilizes Linear

Technology’s USB-to-I

C/SMBus/PMBus controller to

communication with one of the many potential targets

including the DC1778A demo board, the DC1890A sock

eted programming board, or a customer target system.

The software also provides an automatic update feature

to keep the revisions current with the latest set of device

drivers and documentation. A great deal of context sen

sitive help is available with LTpowerPlay along with sev-

eral

tutorial demos. Complete information is available at

http://www.linear.com/ltpowerplay.

PMBus C

OMMUNICATION AND COMMAND

PROCESSING

The LTC3883/LTC3883-1 have a one deep buffer to hold

the last data written for each supported command prior

to processing as shown in Figure 32; Write Command

Data Processing. When the part receives a new command

from the bus, it copies the data into the Write Command

Data Buffer,

indicates to the internal processor that this

command

data needs to be fetched, and converts the

command to its internal format so that it can be executed.

Tw o distinct parallel blocks manage command buffering

and command processing (fetch, convert, and execute) to

ensure the last data written to any command is never lost.