MAX797ESE/GG8 Maxim Integrated Products, MAX797ESE/GG8 Datasheet - Page 21

MAX797ESE/GG8

Manufacturer Part Number

MAX797ESE/GG8

Description

DC/DC Switching Converters Step-Down Controller for CPU Power

Manufacturer

Maxim Integrated Products

Datasheet

1.MAX797CSE.pdf (32 pages)

Specifications of MAX797ESE/GG8

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These equations are “worst-case” with 45 degrees of

phase margin to ensure jitter-free fixed-frequency opera-

tion and provide a nicely damped output response for

zero to full-load step changes. Some cost-conscious

designers may wish to bend these rules by using less

expensive (lower quality) capacitors, particularly if the

load lacks large step changes. This practice is tolerable,

provided that some bench testing over temperature is

done to verify acceptable noise and transient response.

There is no well-defined boundary between stable and

unstable operation. As phase margin is reduced, the

first symptom is a bit of timing jitter, which shows up as

blurred edges in the switching waveforms where the

scope won’t quite sync up. Technically speaking, this

(usually) harmless jitter is unstable operation, since the

switching frequency is now non-constant. As the

capacitor quality is reduced, the jitter becomes more

pronounced and the load-transient output voltage

waveform starts looking ragged at the edges.

Eventually, the load-transient waveform has enough

ringing on it that the peak noise levels exceed the

allowable output voltage tolerance. Note that even with

zero phase margin and gross instability present, the

output voltage noise never gets much worse than I

x R

Designers of RF communicators or other noise-sensi-

tive analog equipment should be conservative and

stick to the guidelines. Designers of notebook comput-

ers and similar commercial-temperature-range digital

systems can multiply the R

without hurting stability or transient response.

The output voltage ripple is usually dominated by the

ESR of the filter capacitor and can be approximated as

full equation for ripple in the continuous mode is

idle mode, the inductor current becomes discontinuous

with high peaks and widely spaced pulses, so the

noise can actually be higher at light load compared to

full load. In idle mode, the output ripple can be calcu-

lated as:

RIPPLE

NOISE(p-p)

ESR

———————————————————

(under constant loads, at least).

0.0003 x L x [1 / V

x R

ESR

= I

NOISE(p-p)

. There is also a capacitive term, so the

RIPPLE

______________________________________________________________________________________

x (R

SENSE

= —————— +

Synchronous Rectifier for CPU Power

OUT

ESR

0.02 x R

)

+ 1 / (V

+ 1 / (2 x pi x f x C

x C

SENSE

value by a factor of 1.5

ESR

- V

OUT

)]

Step-Down Controllers with

PEAK

)). In

Buck-plus-flyback applications, sometimes called “cou-

pled-inductor” topologies, need a transformer in order to

generate multiple output voltages. The basic electrical

design is a simple task of calculating turns ratios and

adding the power delivered to the secondary in order to

calculate the current-sense resistor and primary induc-

tance. However, extremes of low input-output differen-

tials, widely different output loading levels, and high turns

ratios can complicate the design due to parasitic trans-

former parameters such as inter-winding capacitance,

secondary resistance, and leakage inductance. For

examples of what is possible with real-world transformers,

see the graphs of Maximum Secondary Current vs. Input

Voltage in the Typical Operating Characteristics.

Power from the main and secondary outputs is lumped

together to obtain an equivalent current referred to the

main output voltage (see Inductor L1 for definitions of

parameters). Set the value of the current-sense resistor

at 80mV / I

where: V

In positive-output (MAX796) applications, the trans-

former secondary return is often referred to the main

output voltage rather than to ground in order to reduce

the needed turns ratio. In this case, the main output

voltage must first be subtracted from the secondary

voltage to obtain V

TOTAL

Turns Ratio N = ——————————————

L(primary) = —————————————

= P

ondary-output voltage

rectifier

output voltage (from the Electrical

Characteristics)

synchronous-rectifier MOSFET

resistor

= the sum of the output power from all outputs

SEC

FWD

OUT(MIN)

RECT

SENSE

TOTAL

rent referred to V

TOTAL

is the minimum required rectified sec-

is the forward drop across the secondary

is the on-state voltage drop across the

is the voltage drop across the sense

SEC

is the minimum value of the main

/ V

OUT

OUT(MIN)

IN(MAX)

OUT

(MAX796/MAX799 Only)

= the equivalent output cur-

OUT

SEC

Transformer Design

IN(MAX)

x f x I

+ V

RECT

FWD

TOTAL

- V

+ V

OUT

x LIR

SENSE

)

MAX797ESE/GG8 Maxim Integrated Products, MAX797ESE/GG8 Datasheet - Page 21

MAX797ESE/GG8

Specifications of MAX797ESE/GG8

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