Pmics with dynamic core for pdas and smart phones, Table 4. compensation parameters, Table 5. typical compensation values – Rainbow Electronics MAX1587A User Manual

MAX1586A/MAX1586B/MAX1587A

High-Efficiency, Low-I

Q

PMICs with

Dynamic Core for PDAs and Smart Phones

______________________________________________________________________________________

25

must also have low impedance at the switching fre-
quency. Ceramic, polymer, and tantalum capacitors
are suitable, with ceramic exhibiting the lowest ESR
and lowest high-frequency impedance.

Output ripple with a ceramic output capacitor is
approximately:

V

RIPPLE

= I

L(PEAK)

[1 / (2π x f

OSC

x C

OUT

)]

If the capacitor has significant ESR, the output ripple
component due to capacitor ESR is:

V

RIPPLE(ESR)

= I

L(PEAK)

x ESR

Output capacitor specifics are also discussed in the
Compensation and Stability section.

Compensation and Stability

The relevant characteristics for REG1, REG2, and
REG3 compensation are:

1) Transconductance (from FB_ to CC_), gm

EA

2) Current-sense amplifier transresistance, R

CS

3) Feedback regulation voltage, V

FB

(1.25V)

4) Step-down output voltage, V

OUT

, in V

5) Output load equivalent resistance, R

LOAD

= V

OUT

/

I

LOAD

The key steps for step-down compensation are:

1) Set the compensation RC zero to cancel the R

LOAD

C

OUT

pole.

2) Set the loop crossover at or below approximately

1/10th the switching frequency.

For example, with V

IN(MAX)

= 5V, V

OUT

= 2.5V for

REG2, and I

OUT

= 800mA, then R

LOAD

= 3.125Ω. For

REG2, R

CS

= 0.75V/A and gm

EA

= 87µS.

Choose the crossover frequency, f

C

≤ f

OSC

/ 10.

Choose 100kHz. Then calculate the value of the com-
pensation capacitor, C

C

:

C

C

= (V

FB

/ V

OUT

) x (R

LOAD

/ R

CS

) x (gm / (2π x f

C

))

= (1.25 / 2.5) x (3.125 / 0.75) x (87 x 10

-6

/ (6.28

x 100,000)) = 289pF

Choose 330pF, the next highest standard value.

Now select the compensation resistor, R

C

, so transient-

droop requirements are met. As an example, if 3% tran-
sient droop is allowed for the desired load step, the
input to the error amplifier moves 0.03 x 1.25V, or
37.5mV. The error-amplifier output drives 37.5mV x
gm

EA

, or I

EAO

= 37.5mV x 87µS = 3.26µA across R

C

to

provide transient gain. Find the value of R

C

that allows

the required load-step swing from:

R

C

= R

CS

x I

IND(PK)

/ I

EAO

where I

IND(PK)

is the peak inductor current. In a step-

down DC-DC converter, if L

IDEAL

is used, output cur-

rent relates to inductor current by:

I

IND(PK)

= 1.25 x I

OUT

So for an 800mA output load step with V

IN

= 3.6V and

V

OUT

= 2.5V:

R

C

= R

CS

x I

IND(PK)

/ I

EAO

= (0.75V/A) x

(1.25 x 0.8A) / 3.26µA = 230kΩ

We choose 240kΩ. Note that the inductor does not limit
the response in this case since it can ramp at (V

IN

-

V

OUT

) / L, or (3.6 - 2.5) / 3.3µH = 242mA/µs.

The output filter capacitor is then selected so that the
C

OUT

R

LOAD

pole cancels the R

C

C

C

zero:

C

OUT

x R

LOAD

= R

C

x C

C

For the example:

R

LOAD

= V

OUT

x I

LOAD

= 2.5V / 0.8A =

3.125Ω

C

OUT

= R

C

x C

C

/ R

LOAD

= 240kΩ x 330pF /

3.125Ω = 25µF

We choose 22µF.

Recalculate R

C

using the selected C

OUT

.

R

C

= C

OUT

x R

LOAD

/ C

C

= 208kΩ

PARAMETER

REG1

REG2

REG3

Error-Amplifier

Transconductance, gmEA

87µS

87µS

68µS

Current-Sense Amp

Transresistance, R

CS

0.5V/A

0.75V/A

1.25V/A

Table 4. Compensation Parameters

COMPONENT OR

PARAMETER

REG1

REG2

REG3

V

OUT

3.3V

2.5V

1.3V

Output Current

1300mA

900mA

500mA

Inductor

3.3µH

6.8µH

10µH

Load-Step Droop

3%

3%

3%

Loop Crossover Freq (fC)

100kHz

100kHz

100kHz

C

C

330pF

270pF

330pF

R

C

240k

Ω

240k

Ω

240k

Ω

C

OUT

22µF

22µF

22µF

Table 5. Typical Compensation Values