MAX1636EAP+T (Maxim) PDF资料下载 Datasheet(21/23 页)

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参数资料

型号：	MAX1636EAP+T
厂商：	Maxim Integrated Products
文件页数：	21/23页
文件大小：	0K
描述：	IC REG CTRLR BUCK PWM CM 20-SSOP
标准包装：	2,000
PWM 型：	电流模式，混合
输出数：	1
频率 - 最大：	330kHz
占空比：	99%
电源电压：	3.15 V ~ 30 V
降压：	是
升压：	无
回扫：	无
反相：	无
倍增器：	无
除法器：	无
Cuk：	无
隔离：	无
工作温度：	-40°C ~ 85°C
封装/外壳：	20-SSOP（0.209"，5.30mm 宽）
包装：	带卷 (TR)

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Low-Voltage, Precision Step-Down

Controller for Portable CPU Power

Table 6. Low-Voltage Troubleshooting Chart

SYMPTOM

CONDITION

ROOT CAUSE

SOLUTION

Increase bulk output capacitance

Sag or droop in V OUT under

step-load change

Low V IN -V OUT

differential, <1.5V

Limited inductor-current

slew rate per cycle.

per formula (see Low-Voltage

Operation section). Reduce inductor

value.

Dropout voltage is too high

(V OUT follows V IN as V IN

decreases)

Unstable—jitters between

different duty factors and

frequencies

Poor efficiency

Won’t start under load or

quits before battery is

completely dead

Low V IN -V OUT

differential, <1V

Low V IN -V OUT

differential, <0.5V

Low input voltage, <5V

Low input voltage, <4.5V

Maximum duty-cycle limits

exceeded.

Normal function of internal

low-dropout circuitry.

VL linear regulator is going

into dropout and isn’t provid-

ing good gate-drive levels.

VL output is so low that it

hits the VL UVLO threshold.

Reduce operation to 200kHz.

Reduce MOSFET on-resistance and

coil DCR.

Increase the minimum input voltage

or ignore.

Use a small 20mA Schottky diode

for boost diode. Supply VL from an

external source.

Supply VL from an external source

other than V IN , such as the system

+5V supply.

where R DC is the DC resistance of the coil, R DS(ON) is

the MOSFET on-resistance, and R SENSE is the current-

sense resistor value. The R DS(ON) term assumes identi-

cal MOSFETs for the high-side and low-side switches

because they time-share the inductor current. If the

MOSFETs are not identical, their losses can be estimat-

ed by averaging the losses according to duty factor.

PD(tran) = transition loss = V IN x I LOAD x f x 3/2 x

[(V IN C RSS / I GATE ) + 20ns]

where C RSS is the reverse transfer capacitance of the

high-side MOSFET (a data-sheet parameter), I GATE is

the DH gate-driver peak output current (1.5A typ), and

20ns is the rise/fall time of the DH driver (20ns typ).

P(gate) = Q g x f x VL

where VL is the internal logic-supply voltage (+5V), and

Q g is the sum of the gate-charge values for low-side

and high-side switches. For matched MOSFETs, Q g is

twice the data-sheet value of an individual MOSFET. If

V OUT is set to less than 4.5V, replace VL in this equa-

tion with V BATT . In this case, efficiency can be

improved by connecting VL to an efficient 5V source,

such as the system +5V supply.

P(diode) = diode conduction losses =

I LOAD x V FWD x t D x f

where t D is the diode-conduction time (120ns typ), and

V FWD is the forward voltage of the diode. This power is

dissipated in the MOSFET body diode if no external

Schottky diode is used.

P(cap) = input capacitor ESR loss = I RMS2 x R ESR

where I RMS is the input ripple current as calculated in

the Input Capacitor Value section.

Light-Load Efficiency Considerations

Under light loads, the PWM operates in discontinuous

mode, where the inductor current discharges to zero at

some point during the switching cycle. This makes the

inductor current’s AC component high compared to the

load current, which increases core losses and I 2 R loss-

es in the output filter capacitors. For best light-load effi-

ciency, use MOSFETs with moderate gate-charge

levels and use ferrite, MPP, or other low-loss core mate-

rial. Avoid powdered-iron cores; even Kool-Mu

(aluminum alloy) is not as good as ferrite.

PC Board Layout Considerations

Good PC board layout is required in order to achieve

specified noise, efficiency, and stable performance.

The PC board layout artist must be given explicit

instructions, preferably a pencil sketch showing the

placement of power-switching components and high-

current routing. See the PC board layout in the

MAX1636 evaluation kit manual for examples. A ground

plane is essential for optimum performance. In most

applications, the circuit will be located on a multi-layer

board, and full use of the four or more copper layers

is recommended. Use the top layer for high-current

______________________________________________________________________________________

21

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