Datasheet

ManualsBrandsMAXIM INTEGRATED ManualsPMICsPMIC - voltage regulators - DC DC switch controllers TSSOP 28 EP

MAX5066

Configurable, Single-/Dual-Output, Synchronous

Buck Controller for High-Current Applications

______________________________________________________________________________________ 13

oscillator. The PWM on-cycle terminates when the ramp

voltage exceeds the error voltage from the current-error

amplifier (CEA1).

The outer voltage control loop consists of the voltage-

error amplifier (VEA1). The noninverting input (EAN1) is

externally connected to the midpoint of a resistive volt-

age-divider from OUT1 to EAN1 to AGND. The voltage

loop gain is set by using an external resistor from the

output of this amplifier (EAOUT1) to its inverting input

(EAN1). The noninverting input of (VEA1) is connected

to the 0.61V internal reference.

Peak-Current Comparator

The peak-current comparator (see Figure 3) monitors

the voltage across the current-sense resistor (R

SENSE

)

and provides a fast cycle-by-cycle current limit with a

threshold of 52.5mV. Note that the average current-limit

threshold of 22.5mV still limits the output current during

short-circuit conditions. To prevent inductor saturation,

select an output inductor with a saturation current

specification greater than the average current limit of

22.5mV/R

SENSE

. Proper inductor selection ensures that

only extreme conditions trip the peak-current compara-

tor, such as a damaged output inductor. The typical

propagation delay of the peak current-limit comparator

is 260ns.

Current-Error Amplifier

The MAX5066 has two dedicated transconductance

current-error amplifiers CEA1 and CEA2 with a typical

of 550µS and 320µA output sink and source capabil-

ity. The current-error amplifier outputs (CLP1 and CLP2)

serve as the inverting input to the PWM comparators.

CLP1 and CLP2 are externally accessible to provide fre-

quency compensation for the inner current loops (see

CFF

, C

, and R

in Figure 2). Compensate the cur-

rent-error amplifier such that the inductor current down

slope, which becomes the up slope at the inverting

input of the PWM comparator, is less than the slope of

the internally generated voltage ramp (see the

Compensation section).

PWM Comparator and R-S Flip-Flop

The PWM comparator (CPWM1 or CPWM2) sets the

duty cycle for each cycle by comparing the current-

error amplifier output to a 2V

P-P

ramp. At the start of

each clock cycle an R-S flip-flop resets and the high-

side drivers (DH1 and DH2) turn on. The comparator

sets the flip-flop as soon as the ramp voltage exceeds

the current-error amplifier output voltage, thus terminat-

ing the on cycle.

Voltage Error Amplifier

The voltage-error amplifier (VEA_) sets the gain of the

voltage control loop. Its output clamps to 1.14V and

-0.234V relative to V

= 0.61V. Set the MAX5066 out-

put voltage by connecting a voltage-divider from the

output to EAN_ to GND (see Figure 4). At no load the

output of the voltage error amplifier is zero.

Use the equation below to calculate the no load voltage:

The voltage at full load is given by:

where ∆V

OUT

is the voltage-positioning window

described in the Adaptive Voltage Positioning section.

Adaptive Voltage Positioning

Powering new-generation ICs requires new techniques

to reduce cost, size, and power dissipation. Voltage

positioning (Figure 5) reduces the total number of out-

put capacitors to meet a given transient response

requirement. Setting the no-load output voltage slightly

higher than the output voltage during nominally loaded

conditions allows a larger downward voltage excursion

when the output current suddenly increases.

Regulating at a lower output voltage under a heavy

load allows a larger upward-voltage excursion when

the output current suddenly decreases. A larger

allowed voltage-step excursion reduces the required

number of output capacitors and/or allows the use of

higher ESR capacitors.

The internal 0.61V reference in the MAX5066 has a toler-

ance of ±0.9%. If we use 0.1% resistors for R

and R

we still have another 4% available for the variation in the

output voltage from nominal. This available voltage

range allows us to reduce the total number of output

capacitors to meet a given transient response require-

ment. This results in a voltage-positioning window as

shown in Figure 5.

From the allowable voltage-positioning window we can

calculate the value of R

from the equation below.

where ∆V

OUT

is the allowable voltage-positioning win-

dow, R

SENSE

is the sense resistor, 36 is the current-

sense amplifier gain, and R

is as shown in Figure 4.

IR R

OUT SENSE

OUT

×××36

∆

OUT FL OUT()

. =×+

⎛

⎝

⎜

⎞

⎠

⎟

−0 6135 1

∆

OUT NL()

. =×+

⎛

⎝

⎜

⎞

⎠

⎟

0 6135 1