LTC4000-1 Datasheet, PDF(33/40 Page) Linear Technology – High Voltage High Current Controller for Battery Charging with Maximum Power Point Control

English

English German Russian Spanish Italian Polish Chinese Japanese Korean French Portuguese	Language :

LTC4000-1 Datasheet, PDF (33/40 Pages) Linear Technology – High Voltage High Current Controller for Battery Charging with Maximum Power Point Control

◁

LTC4000-1

Applications Information

This same procedure is then repeated for the other four

loops: the input voltage regulation, the output voltage

regulation, the battery float voltage regulation and finally

the charge current regulation when VOFB > VOUT(INST_ON).

Note that the resulting optimum values for each of the loops

may differ slightly. The final values of CC and RC are then

selected by combining the results and ensuring the most

conservative response for all the loops. This usually entails

picking the largest value of CC and the smallest value of

RC based on the results obtained for all the loops. In this

particular example, the value of CC is finally set to 47nF

and RC = 14.7kÎ©.

Board Layout Considerations

In the majority of applications, the most important param-

eter of the system is the battery float voltage. Therefore,

the user needs to be extra careful when placing and rout-

ing the feedback resistor RBFB1 and RBFB2. In particular,

the battery sense line connected to RBFB1 and the ground

return line for the LTC4000-1 must be Kelvined back

to where the battery output and the battery ground are

located respectively. Figure 27 shows this Kelvin sense

configuration.

For accurate current sensing, the sense lines from RIS

and RCS (Figure 27) must be Kelvined back all the way

to the sense resistors terminals. The two sense lines of

each resistor must also be routed close together and away

from noise sources to minimize error. Furthermore, cur-

rent filtering capacitors should be placed strategically to

ensure that very little AC current is flowing through these

sense resistors as mentioned in the applications section.

The decoupling capacitors CIN and CBIAS must be placed as

close to the LTC4000-1 as possible. This allows as short

a route as possible from CIN to the IN and GND pins, as

well as from CBIAS to the BIAS and GND pins.

In a typical application, the LTC4000-1 is paired with an

external DC/DC converter. The operation of this converter

often involves high dV/dt switching voltage as well as

high currents. Isolate these switching voltages and cur-

rents from the LTC4000-1 section of the board as much

as possible by using good board layout practices. These

include separating noisy power and signal grounds, having

a good low impedance ground plane, shielding whenever

necessary, and routing sensitive signals as short as pos-

sible and away from noisy sections of the board.

SWITCHING

CONVERTER

GND ITH

ITH

CLN

CC IID IGATE

CSP

RIS

LTC4000-1

CSN

BGATE

BAT

VIN

BFB

GND

FBG

SYSTEM LOAD

RCS

RBFB1

RBFB2

40001 F27

Figure 27. Kelvin Sense Lines Configuration for LTC4000-1

40001f

▷